Variation of 3′-Terminal Fragment of 16S rRNA Gene in Closely Related Species of <Emphasis Type="Italic">Drosophila virilis</Emphasis> Group

Primary sequence of 3′-terminal fragment of the mitochondrial 16S rRNA gene has been determined in 12 Drosophila species of the virilis group. The functionally important elements in secondary structure of the RNA product were defined. The region corresponding to the peptidyltransferase center has been localized. Variation of the 3′-terminal region of 16S rRNA gene has been described in 12 species of the virilis group. Phylogeny of the Drosophila virilis species group is discussed.__________Translated from Genetika, Vol. 41, No. 8, 2005, pp. 1049–1054.Original Russian Text Copyright © 2005 by Sorokina, Mugue, Andrianov, Mitrofanov.     

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.     

Cytogenetic and molecular analysis of the pufferfish Tetraodon fluviatilis (Osteichthyes)

In view of their compact genome, pufferfish (Tetraodontiformes) have been proposed as model animal for the study of the vertebrate genome. Despite such interest, cytogenetic information about puffers is still scanty. To fill this gap, a cytogenetic analysis of T. fluviatilis has been performed using both classical and molecular techniques. C-banding, followed by DAPI staining, evidenced that in T. fluviatilis, like all other puffer species so far examined, heterochromatin is essentially AT-rich and it is located at centromeres, whereas staining with CMA₃, silver staining and FISH with a 28S ribosomal RNA gene DNA probe showed 2–4 nucleolar organizing regions (NORs) located in heterochromatic regions in the considered puffer species. FISH with the 5S probe put in evidence both in T. fluviatilis and in T. nigroviridis only a 5S cluster per haploid genome that is physically unlinked with the major ribosomal RNA genes including the 28S rRNA genes. Hybridization with the (TTAGGG)_n probe showed in all the puffers brightly fluorescent signals uniform both in size and intensity at the end of all the chromosomes. Finally, mariner-like elements (MLEs) have been identified in T. fluviatilis and they have located into the NOR-associated heterochromatin.     

Genetic evidence for 18S rRNA binding and an Rps19p assembly function of yeast nucleolar protein Nep1p

The nucleolar protein Nep1 and its human homologue were previously shown to be involved in the maturation of 18S rRNA and to interfere directly or indirectly with a methylation reaction. Here, we report that the loss-of-function mutation Δsnr57 and multicopy expression of the ribosomal 40S subunit protein 19 (Rps19p) can partially suppress the Saccharomyces cerevisiae Δnep1 growth defect. SnR57 mediates 2′-O-ribose-methylation of G₁₅₇₀ in the 18S rRNA. By performing a three-hybrid screen, we isolated several short RNA sequences with strong binding affinity to Nep1p. All isolated RNAs shared a six-nucleotide consensus motif C/UUCAAC. Furthermore, one of the isolated RNAs exactly corresponded to nucleotides 1553–1577 of the 18S rRNA, which includes G₁₅₇₀, the site of snR57-dependent 18S rRNA methylation. From protein–protein crosslink data and the cryo-EM map of the S. cerevisiae small ribosomal subunit, we suggest that Rps19p is localized in close vicinity to the Nep1p 18S rRNA binding site. Our results suggest that Nep1p binds adjacent to helix 47 of the 18S rRNA and possibly supports the association of Rps19p to pre-ribosomal particles.     

Single-chain ribosome inactivating proteins from plants depurinate Escherichia coli 23S ribosomal RNA

The rRNA N-glycosidase activities of the catalytically active A chains of the heterodimeric ribosome inactivating proteins (RIPs) ricin and abrin, the single-chain RIPs dianthin 30, dianthin 32, and the leaf and seed forms of pokeweed antiviral protein (PAP) were assayed on E. coli ribosomes. All of the single-chain RIPs were active on E. coli ribosomes as judged by the release of a 243 nucleotide fragment from the 3′ end of 23S rRNA following aniline treatment of the RNA. In contrast, E. coli ribosomes were refractory to the A chains of ricin and abrin. The position of the modification of 23S rRNA by dianthin 32 was determined by primer extension and found to be A₂₆₆₀, which lies in a sequence that is highly conserved in all species.     

Shared requirements for key residues in the antibiotic resistance enzymes ErmC and ErmE suggest a common mode of RNA recognition

Erythromycin-resistance methyltransferases are SAM dependent Rossmann fold methyltransferases that convert A2058 of 23S rRNA to m⁶ ₂A2058. This modification sterically blocks binding of several classes of antibiotics to 23S rRNA, resulting in a multidrug-resistant phenotype in bacteria expressing the enzyme. ErmC is an erythromycin resistance methyltransferase found in many Gram-positive pathogens, whereas ErmE is found in the soil bacterium that biosynthesizes erythromycin. Whether ErmC and ErmE, which possess only 24% sequence identity, use similar structural elements for rRNA substrate recognition and positioning is not known. To investigate this question, we used structural data from related proteins to guide site-saturation mutagenesis of key residues and characterized selected variants by antibiotic susceptibility testing, single turnover kinetics, and RNA affinity–binding assays. We demonstrate that residues in α4, α5, and the α5-α6 linker are essential for methyltransferase function, including an aromatic residue on α4 that likely forms stacking interactions with the substrate adenosine and basic residues in α5 and the α5-α6 linker that likely mediate conformational rearrangements in the protein and cognate rRNA upon interaction. The functional studies led us to a new structural model for the ErmC or ErmE-rRNA complex.     

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 nucleolar SUMO-specific protease SENP3 reverses SUMO modification of nucleophosmin and is required for rRNA processing

The ubiquitin-like SUMO system functions by a cyclic process of modification and demodification, and recent data suggest that the nucleolus is a site of sumoylation-desumoylation cycles. For example, the tumour suppressor ARF stimulates sumoylation of nucleolar proteins. Here, we show that the nucleolar SUMO-specific protease SENP3 is associated with nucleophosmin (NPM1), a crucial factor in ribosome biogenesis. SENP3 catalyses desumoylation of NPM1-SUMO2 conjugates in vitro and counteracts ARF-induced modification of NPM1 by SUMO2 in vivo. Intriguingly, depletion of SENP3 by short interfering RNA interferes with nucleolar ribosomal RNA processing and inhibits the conversion of the 32S rRNA species to the 28S form, thus phenocopying the processing defect observed on depletion of NPM1. Moreover, mimicking constitutive modification of NPM1 by SUMO2 interferes with 28S rRNA maturation. These results define SENP3 as an essential factor for ribosome biogenesis and suggest that deconjugation of SUMO2 from NPM1 by SENP3 is critically involved in 28S rRNA maturation.     

Ribosome biogenesis requires a highly diverged XRN family 5′→3′ exoribonuclease for rRNA processing in Trypanosoma brucei

Although biogenesis of ribosomes is a crucial process in all organisms and is thus well conserved, Trypanosoma brucei ribosome biogenesis, of which maturation of rRNAs is an early step, has multiple points of divergence. Our aim was to determine whether in the processing of the pre-rRNA precursor molecule, 5′→3′ exoribonuclease activity in addition to endonucleolytic cleavage is necessary in T. brucei as in other organisms. Our approach initiated with the bioinformatic identification of a putative 5′→3′ exoribonuclease, XRNE, which is highly diverged from the XRN2/Rat1 enzyme responsible for rRNA processing in other organisms. Tagging this protein in vivo allowed us to classify XRNE as nucleolar by indirect immunofluorescence and identify by copurification interacting proteins, many of which were ribosomal proteins, ribosome biogenesis proteins, and/or RNA processing proteins. To determine whether XRNE plays a role in ribosome biogenesis in procyclic form cells, we inducibly depleted the protein by RNA interference. This resulted in the generation of aberrant preprocessed 18S rRNA and 5′ extended 5.8S rRNA, implicating XRNE in rRNA processing. Polysome profiles of XRNE-depleted cells demonstrated abnormal features including an increase in ribosome small subunit abundance, a decrease in large subunit abundance, and defects in polysome assembly. Furthermore, the 5′ extended 5.8S rRNA in XRNE-depleted cells was observed in the large subunit, monosomes, and polysomes in this gradient. Therefore, the function of XRNE in rRNA processing, presumably due to exonucleolytic activity very early in ribosome biogenesis, has consequences that persist throughout all biogenesis stages.     

Partial purification and characterization of mitochondrial DNA polymerase from Plasmodium falciparum

Mitochondria of chloroquine-resistant Plasmodium falciparum (K1 strain) were isolated from mature trophozoites by differential centrifugation. The mitochondrial marker enzyme cytochrome c reductase was employed to monitor the steps of mitochondria isolation. Partial purification of DNA polymerase from P. falciparum mitochondria was performed using fast protein liquid chromatography (FPLC). DNA polymerase of P. falciparum mitochondria was characterized as a γ-like DNA polymerase based on its sensitivity to the inhibitors aphidicolin, N-ethylmaleimide and 9-β- -arabinofuranosyladenine-5′-triphosphate. In contrast, the enzyme was found to be strongly resistant to 2′,3′-dideoxythymidine-5′-triphosphate (IC₅₀>400 μM) and differed in this aspect from the human homologue, possibly indicating structural differences between human and P. falciparum DNA polymerase γ. In addition, the DNA polymerase of parasite mitochondria was shown to be resistant (IC₅₀>1 mM) to the nucleotide analogue (S)-1-[3-hydroxy-2-phosphonylmethoxypropyl]adenine diphosphate (HPMPApp).     

Enzymes related to catecholamine biosynthesis in Tetrahymena pyriformis. Presence of GTP cyclohydrolase I.

We first identified GTP cyclohydrolase I activity (EC 3.5.4.16) in the ciliated protozoa, Tetrahymena pyriformis. The V_max value of the enzyme in the cellular extract of T. pyriformis was 255 pmol mg⁻¹ protein h⁻¹. Michaelis–Menten kinetics indicated a positive cooperative binding of GTP to the enzyme. The GTP concentration producing half-maximal velocity was 0.8 mM. By high-performance liquid chromatography (HPLC) with fluorescence detection, a major peak corresponding to -monapterin (2-amino-4-hydroxy-6-[(1′R,2′R)-1′,2′,3′-trihydroxypropyl]pteridine, -threo-neopterin) and minor peaks of -erythro-neopterin and -erythro-biopterin were found to be present in the cellular extract of Tetrahymena. Thus, it is strongly suggested that Tetrahymena converts GTP into unconjugated pteridine derivatives. In this study, dopamine was detected as the major catecholamine, while neither epinephrine nor norepinephrine was identified. Indeed, this protozoa was shown to possess the activity of a dopamine synthesizing enzyme, aromatic -amino acid decarboxylase. On the other hand, activities of tyrosine hydroxylase or tyrosinase which converts tyrosine into dopa, the substrate of aromatic -amino acid decarboxylase, could not be detected in this protozoa. Furthermore, neither dopamine β-hydroxylase activity nor phenylethanolamine N-methyltransferase activity could be identified by the HPLC methods.     

The effect of serum on the calcium content of BALB/c 3T3 mouse cells

The 5'-termini of purified rat liver nucleolar and cytoplasmic 28S ribosomal RNA (rRNA) are precisely located within the homologous rDNA sequence by S1 nuclease protection mapping using an appropriate rDNA restriction fragment. The 5'-termini of nucleolar 28S rRNA are heterogeneous in length. The bulk of the nucleolar 28S rRNA map within two CTC motifs in rDNA located in the internal transcribed spacer 2 at the 50-60 and 5-15 bp upstream from the site of the homogeneous 5'-terminus of the cytoplasmic 28S rRNA. These results provide direct proof that nucleolar 28S rRNA molecules contain excess sequences at their 5'-termini and require further processing to generate the mature cytoplasmic 28S rRNA.     

Non-cognizable ribonucleotide, 2′AMP, binds to a mutant ribonuclease T1 (Y45W) at a new base-binding site but not at the guanine-recognition site

Complex of a mutant ribonuclease T₁ (Y4SW) with a non-cognizable ribonucleotide, 2′AMP, has been determined and refined by X-ray diffraction at 1.7 Å resolution. The 2′AMP molecule locates at a new base-binding site which is remote from the guanine-recognition site, where 2′GMP was found to be bound. The nucleotide adopts the anti conformation of the glycosidic bond and C3′-exo sugar pucker. There exists a single hydrogen bond between the adenine base and the enzyme, and, therefore, the site found is apparently a non-specific binding site. The results indicate that the binding of 2′AMP to the guanine-recognition site is weaker than that to the new binding site.