Properties of a discrete high molecular weight poly(A) containing mitochondrial RNA

Pulse-labeled mitochondrial RNA from hamster cells contains a number of discrete high molecular weight poly[A(+)] and poly[A(?)] RNAs. Characterization of the largest and most plentiful of the poly[A(+)] RNAs, the “20S_E RNA,” showed it to be a labile, unmethylated component with a molecular weight ～- 730,000. Hybridization of the 20S_E RNA to mtDNA was 60–70% inhibited in the presence of excess 17S rRNA, suggesting a significant degree of primary sequence homology between these RNA species. In vitro treatment with RNAse III converted the 20S_E RNA to a poly[A(?)] “17S” product, while similar treatment of mitochondrial 17S rRNA or a poly[A(+)] 12S_E RNA had no effect on these RNAs. These data support the proposition that the 20S_E RNA is a precursor to the 17S rRNA.     

Small RNAs of Rous Sarcoma Virus: Characterization by Two-Dimensional Polyacrylamide Gel Electrophoresis and Fingerprint Analysis

Approximately 15 to 20 different species of small (4 to 7S) RNAs have been purified by two-dimensional polyacrylamide gel electrophoresis of RNA isolated from virions of Schmidt-Ruppin D strain of Rous sarcoma virus. Each species of small RNA has been isolated free of 70S RNA; nine of them, including 5S and 7S RNAs, were also found associated with the 70S genomic RNA. Most of the 4S RNAs are present at an average of less than one copy per virion. The 4S RNAs have T1 RNase (EC 2.7.7.26) fingerprints, which are very similar to those of tRNAs. One of the smallest 4S RNAs, which can act as a primer for initiation of RNA-directed DNA synthesis, is associated with the 70S RNA in 1 to 2 copies per complex, whereas an additional 6 to 8 copies of this molecule are free.     

Precursors of 5 S ribosomal RNA in Bacillus subtilis

Bacillus subtilis 168 accumulates subnormal quantities of mature 5 S ribo-somal RNA in the presence of inhibitors of protein synthesis, such as chloramphenicol, or during pulse-labeling experiments. However, two RNA species, evidently precursors of m5 rRNA and therefore designated as p5_A and p5_B, do accumulate under these conditions. These RNA species are substantially longer than B. subtilis m5 rRNA: p5_A is about 179 nucleotides in length and p5_B is composed of approximately 152 nucleotides. The sum of p5_A, p5_B and m5 rRNA accumulating in the absence of protein synthesis, less excess chain length associated with p5_A and p5_B, equals the expected quantities of m5 rRNA in growing cells. p5_A and p5P_B both contain all t₁ RNase-generated oligonucleotides characteristic of m5 rRNA plus additional sequences. At least the 5′ termini of p5_A and p5_B differ from that of m5. If chloramphenicol is removed from a culture in which p5_A and p5_B have accumulated and further RNA synthesis is inhibited, then a quantitative reciprocal loss of p5_A and p5_B occurs as m5 rRNA accumulates. No evidence suggests any p5_A to p5_B transition under these conditions.     

Characterization and mutational analysis of yeast Dbp8p, a putative RNA helicase involved in ribosome biogenesis

RNA helicases of the DEAD box family are involved in almost all cellular processes involving RNA molecules. Here we describe functional characterization of the yeast RNA helicase Dbp8p (YHR169w). Our results show that Dbp8p is an essential nucleolar protein required for biogenesis of the small ribosomal subunit. In vivo depletion of Dbp8p resulted in a ribosomal subunit imbalance due to a deficit in 40S ribosomal subunits. Subsequent analyses of pre-rRNA processing by pulse–chase labeling, northern hybridization and primer extension revealed that the early steps of cleavage of the 35S precursor at sites A₁ and A₂ are inhibited and delayed at site A₀. Synthesis of 18S rRNA, the RNA moiety of the 40S subunit, is thereby blocked in the absence of Dbp8p. The involvement of Dbp8p as a bona fide RNA helicase in ribosome biogenesis is strongly supported by the loss of Dbp8p in vivo function obtained by site-directed mutagenesis of some conserved motifs carrying the enzymatic properties of the protein family.     

pH dependent stabilization of S2QA − and S2QB − charge pairs studied by thermoluminescence

The pH dependence of emission peak temperature and decay time of thermoluminescence arising from S₂Q_B ^– and S₂Q_A ^– recombinations demonstrates that a stabilization of S₂Q_B ^– occurs at low pH whereas stabilization of S₂Q_A ^– occurs at high pH. Based on comparative analysis of thermoluminescence parameters of the two types of recombination, we suggest that in the pH range between 5.3 and 7.5, E_m(S₂/S₁) and E_m(Q_A/Q_A ^–) are constant, but E_m(Q_B/Q_B ^–) gradually increases with decreasing pH, while in the pH range between 7.5 and 8.5, an unusual change occurs on S₂Q_A ^– charge pair, which is interpreted as either a decrease in E_m(S₂/S₁) or an increase in E_m(Q_A/Q_A ^–).     

Spatial transcription of CYP1A in fish liver

Background  

The aim of this work was to study how evenly detoxifying genes are transcribed spatially in liver tissue of fish. Ten Atlantic salmon Salmo salar were intraperitoneally injected with 50 mg/kg of the strong CYP1A inducer β-naphthoflavone and liver tissue harvested seven days later. The liver from 10 control and 10 exposed fish were split into eight sections, RNA extracted and three reference (β-actin, elongation factor 1A_B (EF1A_B)) and two detoxifying genes (CYP1A and GST) quantified with real-time RT-PCR. The cellular localization of the EF1A_B and CYP1A mRNA in the liver of control and β-naphthoflavone treated fish was then determined by in situ hybridization (ISH) using EF1A_B and CYP1A biotinylated oligonucleotide probes.     

Comparison of the crystallin mRNA populations from rat,calf and duck lens. Evidence for a longer αA2-mRNA and two distinct αB2-mRNAs in the birds

Total cytoplasmic poly(A)-containing RNA from rat, calf and duck lens was fractionated by electrophoresis in methylmercury hydroxide-containing agarose gels. RNA electrophoresed in parallel lanes was either transferred onto nitrocellulose and hybridized with total cDNA synthesized on the initial mRNA or was recovered from individual gel fractions for in vitro translation in a reticulocyte cell-free system. This allowed the identification and size-characterization of individual mRNA species encoding α-, β-, γ- and δ-crystallin polypeptides. The 14 S mRNA fraction of rat lens comprises two αA₂-mRNAs of approximately 1250 and 1350 nucleotides and the αA^Ins-mRNA with a size similar to that of the largest αA₂-mRNA. The calf lens 14 S mRNA fraction harbors a heterogeneous population of αA₂-mRNA. In the same fraction another mRNA encoding a polypeptide, designated X, has been found sharing no homology with αA sequences. The duck lens αA₂-mRNA appears to be 400–450 bases longer than the rat and calf lens αA₂-mRNAs. Furthermore, in contrast to the single αB₂-mRNA in rat and calf lens, two αB₂-mRNAs have been identified in duck lens, one, the major species, similar in size to the αB₂-mRNA in rat and calf lens (800 bases), and the other species 700 nucleotides longer. The large size differences among the αA₂- and αB₂-mRNAs most likely reside in their 3′-untranslated sequences.     

In vitro association of unique species of cellular 4S RNA with 35S RNA of RNA tumor viruses

Unique 4S RNA species from AKR mouse embryo cells hybridize with AKR murine leukemia virus and avian myeloblastosis virus 35S RNAs $\text{in vitro}$. Analyses by reversed-phase column chromatography indicate that the major 4S species that hybridize with the two viral RNAs are probably the same. A 4S RNA species with similar chromatographic properties is a major component of the AKR viral 4S RNA which associates with the viral 70S RNA $\text{in vivo}$.     

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.     

RNA-protein interactions in the ribosome. II. Binding of ribosomal proteins to isolated fragments of the 16 S RNA

Specific fragments of the 16 S ribosomal RNA of Escherichia coli have been isolated and tested for their ability to interact with proteins of the 30 S ribosomal subunit. The 12 S RNA, a 900-nucleotide fragment derived from the 5′-terminal portion of the 16 S RNA, was shown to form specific complexes with proteins S4, S8, S15, and S20. The stoichiometry of binding at saturation was determined in each case. Interaction between the 12 S RNA and protein fraction $\text{S}\text{16}\text{S}\text{17}$ was detected in the presence of S4, S8, S15 and S20; only these proteins were able to bind to this fragment, even when all 21 proteins of the 30 S subunit were added to the reaction mixture. Protein S4 also interacted specifically with the 9 S RNA, a fragment of 500 nucleotides that corresponds to the 5′-terminal third of the 16 S RNA, and protein S15 bound independently to the 4 S RNA, a fragment containing 140 nucleotides situated toward the middle of the RNA molecule. None of the proteins interacted with the 600-nucleotide 8 S fragment that arose from the 3′-end of the 16 S RNA.When the 16 S RNA was incubated with an unfractionated mixture of 30 S subunit proteins at 0 °C, 10 to 12 of the proteins interacted with the ribosomal RNA to form the reconstitution intermediate (RI) particle. Limited hydrolysis of this particle with T₁ ribonuclease yielded 14 S and 8 S subparticles whose RNA components were indistinguishable from the 12 S and 8 S RNAs isolated from digests of free 16 S RNA. The 14 S subparticle contained proteins S6 and S18 in addition to the RNA-binding proteins S4, S8, S15, S20 and $\text{S}\text{16}\text{S}\text{17}$. The 8 S subparticle contained proteins S7, S9, S13 and S19. These findings serve to localize the sites at which proteins incapable of independent interaction with 16 S RNA are fixed during the early stages of 30 S subunit assembly.     

All three functional domains of the large ribosomal subunit protein L25 are required for both early and late pre-rRNA processing steps in Saccharomyces cerevisiae

Mutational analysis has shown that the integrity of the region in domain III of 25S rRNA that is involved in binding of ribosomal protein L25 is essential for the production of mature 25S rRNA in the yeast Saccharomyces cerevisiae. However, even structural alterations that do not noticeably affect recognition by L25, as measured by an in vitro assay, strongly reduced 25S rRNA formation by inhibiting the removal of ITS2 from the 27S_B precursor. In order to analyze the role of L25 in yeast pre-rRNA processing further we studied the effect of genetic depletion of the protein or mutation of each of its three previously identified functional domains, involved in nuclear import (N-terminal), RNA binding (central) and 60S subunit assembly (C-terminal), respectively. Depletion of L25 or mutating its (pre-)rRNA-binding domain blocked conversion of the 27S_B precursor to 5.8S/25S rRNA, confirming that assembly of L25 is essential for ITS2 processing. However, mutations in either the N- or the C-terminal domain of L25, which only marginally affect its ability to bind to (pre-)rRNA, also resulted in defective ITS2 processing. Furthermore, in all cases there was a notable reduction in the efficiency of processing at the early cleavage sites A₀, A₁ and A₂. We conclude that the assembly of L25 is necessary but not sufficient for removal of ITS2, as well as for fully efficient cleavage at the early sites. Additional elements located in the N- as well as C-terminal domains of L25 are required for both aspects of pre-rRNA processing.     

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.

     

Evolutionary History of 4.5SI RNA and Indication That It Is Functional

To date, the small nuclear 4.5S_I RNA has only been studied in the rat (Rattus norvegicus). Combining PCR and hybridization analyses, we have revealed 4.5S_I RNA homologues sequences in the genomes of four myomorph rodent families (Muridae, Cricetidae, Spalicidae, and Rhizomyidae), and not in other myomorph families (Dipodidae, Zapodidae, Geomyidae, and Heteromyidae) or sciuromorph and caviomorph rodents. By Northern-hybridization, 4.5S_I RNA has been detected in the common rat (R. norvegicus, Muridae), golden hamster (Mesocricetus auratus, Cricetidae), and Russian mole rat (Spalax microphthalmus, Spalacidae), but not in the related great jerboa (Allactaga jaculus, Dipodidae) or in four non-myomorph rodent species tested. cDNA derived from 4.5S_I RNA of M. auratus and S. microphthalmus has been cloned and sequenced. The hamster RNA is found to differ from rat 4.5S_I RNA by only one nucleotide substitution. For the mole rat, two variants of 4.5S_I RNA are detected: short (S) and long (L) with length 101 and 108 nt, respectively. The L variant differs from the S variant as well as from murid and cricetid 4.5S_I RNAs by both a 7 nt insertion and a varying number of nucleotide substitutions. The sequence similarity between the spalacid S-variant and murid/crecitid variants of 4.5S_I RNA is 90%. Judging from species distribution, 4.5S_I RNA genes emerged during the same period of time as the related short interspersed element B2 arose. This occurred after the divergence of Dipodidae lineage but before the branching of Spalicidae/Rhizomyidae lineage from a common myomorph rodent stem. S variant genes seemed to emerge in a common ancestor of spalacids and rhizomyds whereas L variant genes formed in spalacids following the divergence of these two families. The low rate of evolutionary changes of 4.5S_I RNA, at least, in murids and cricetids (6 × 10⁻⁴ substitutions per site per million years), suggests that this RNA is under selection constraint and have a function. This is a remarkable fact if the recent origin and narrow species distribution range of 4.5S_I RNA genes is taken into account. Genes with narrow species distribution are proposed to be referred to as stenogenes. Received: 11 December 2000 / Accepted: 27 August 2001     

Procaryote phylogeny

Summary The catalog of oligonucleotides produced by T₁ ribonuclease digestion ofAerobacter aerogenes 16 S ribosomal RNA has been determined and compared to that characterizingEscherichia coli. It is concluded that the two 16 SrRNAs are approximately 98% similar, making the organisms very closely related.     

RNA--protein interactions in the ribosome. IV. Structure and properties of binding sites for proteins S4, S16/S17 and S20 in the 16S RNA

Proteins S4, S16/S17 and S20 of the 30 S ribosomal subunit of Escherichia coli+ associate with specific binding sites in the 16 S ribosomal RNA. A systematic investigation of the co-operative interactions that occur when two or more of these proteins simultaneously attach to the 16 S RNA indicate that their binding sites lie near to one another. The binding site for S4 has previously been located within a 550-nucleotide RNA fragment of approximately 9 S that arises from the 5′-terminal portion of the 16 S RNA upon limited hydrolysis with pancreatic ribonuclease. The 9 S RNA was unable to associate with S20 and S16/S17, however, either alone or in combination. A fragment of similar size and nucleotide sequence, termed the 9 S¹ RNA, has been isolated following ribonuclease digestion of the complex of 16 S RNA with S20 and S16/S17. The 9 S¹ RNA bound not only S4, but S20 and S16/S17 as well, although the fragment complex was stable only when both of the latter protein fractions were present together. Nonetheless, measurements of binding stoichiometry demonstrated the interactions to be specific under these conditions. A comparison of the 9 S and 9 S¹ RNAs by electrophoresis in polyacrylamide gels containing urea revealed that the two fragments differ substantially in the number and distribution of hidden breaks. Contrary to expectation, the RNA in the ribonucleoprotein complex appeared to be more accessible to ribonuclease than the free 16 S RNA as judged by the smaller average length of the sub-fragments recovered from the 9 S¹ RNA. These results suggest that the binding of S4, S16/S17 and S20 brings about a conformational alteration within the 5′ third of the 16 S RNA.To delineate further the portions of the RNA chain that interact with S4, S16/S17 and S20, specific fragments encompassing subsequences from the 5′ third of the 16 S RNA were sought. Two such fragments, designated 12 S-I and 12 S-II, were purified by polyacrylamide gel electrophoresis from partial T₁ ribonuclease digests of the 16 S RNA. The two RNAs, which contain 290 and 210 nucleotides, respectively, are contiguous and together span the entire 5′-terminal 500 residues of the 16 S RNA molecule. When tested individually, neither 12 S-I nor 12 S-II bound S4, S16/S17 or S20. If heated together at 40 °C in the presence of Mg²⁺ ions, however, the two fragments together formed an 8 S complex which associated with S4 alone, with S16/S17 + S20 in combination, and with S4 + S16/S17 + S20 when incubated with an un fractionated mixture of 30 S subunit proteins. These results imply that each fragment contains part of the corresponding binding sites.