Comparison of the conformation of RNA from phage MS2 and 16S rRNA. Interaction with dyes specific for the secondary structure of native RNA and RNA subjected to hydrolysis by nuclease S1

The interaction of ethidium bromide (EtBr) with double-stranded (ds), and acridine orange (AO) with single-stranded (ss) fragments of 16S rRNA Escherichia coli in a wide range of ionic strength, at various pH, Zn2+ ion concentrations and partial hydrolysis by nuclease S1 was investigated. It was shown that about 90% of the RNA molecule is accessible to both dyes, when the ionic strength is near of 0.01 (pH 7). Approximately half of the RNA becomes inaccessible to dyes, when the ionic strength was increased up to 0.08-0.24 (pH 4.7-7), independent on the presence of Zn2+ ions (10(-3) M). About a half of the ds-, and a quarter of the ss-segments of the RNA, deduced from the secondary structure model were protected from the interaction with EtBr and AO. The hydrolysis of about a half of ss-segments upon addition of the Zn2+ (10(-3) M) ions did not affect the RNA tertiary structure. The experimental data obtained confirm the idea of the existence of some "nucleus" (or "nuclei") within the 16S rRNA molecule. The "nucleus" seems to be inaccessible to the dyes and is very stable to heat denaturation. It was supposed that this structure is organized by means of interaction of some of the parallelly oriented ds-segments, as it was suggested earlier for the phage MS2 RNA structure.     

S1 nuclease hydrolysis of single-stranded nucleic acids with partial double-stranded configuration.

The single-strand specific nuclease S1 from Aspergillus oryzae (EC 3.1.4.21) was purified 600-fold in 16% yield from dried mycelia. Determination of the isoelectric point of S1 nuclease as 4.3-4.4 allowed adjustment of chromatographic conditions such that the enzyme was isolated free of contaminating ribonucleases T1 and T2. S1 nuclease so purified was used for removal of single-stranded portions from the RNA of the Escherichia coli phage MS2, which has a helical content of about 65% in vitro. At 23 degrees, increasing amounts of enzyme converted the RNA to mononucleotides in about equimolar base ratios. No small intermediates of chain length 2-8 were found. At 0 degrees, MS2 RNA hydrolysis was slower and reached, in exhaustive digests, a plateau where 70% of the substrate RNA remained insoluble in 66% EtOH. With [32P]MS2 RNA, strip chart counting of 6% acrylamide-6 M urea electrophoresis patterns of such digests gave recoveries of 80-91% in the form of defined oligomer bands. On 2.5% acrylamide-0.5% agarose gels, the molecular weights of the major oligomers were found to range from 25,000 to 41,000. Similar to purified tRNAArg used as a control, these oligomers were not resistant to pancreatic RNase-RNase T1 hydrolysis at 37 degrees, and were not bound on hydroxylapatite at 50 degrees in 0.14 M sodium phosphate (pH 6.8). Melting of the oligomers gave complex profiles without a clear Tm and showed an increase in A260 of 35% at 93 degrees over that at 28 degrees. Upon formaldehyde denaturation of MS2 RNA prior to S1 nuclease hydrolysis, no resistant oligomers were found.     

The accessibility of phage MS2 RNA to structure specific nucleases in various conditions

The accessibility of ds-and ss-segments of phage MS2 RNA to ds-and ss-specific nucleases (RNase III, nuclease SV and nuclease S1) was studied. The results show that the RNA has hydrolysis sites for all the nucleases used. These sites are unvariable in a wide range of the conditions (ionic strength, pH, bivalent cations and temperature) and are not changed also after denaturation-renaturation of the RNA. This testifies that the distribution and interactions of ds-and ss-segments in the whole molecule are very specific and stable.     

Two distinct conformations of rat liver ribosomal 5S RNA.

Three different conformers of rat liver 5S ribosomal RNA were investigated by partial nuclease cleavage technique using S1 nuclease and cobra venom endoribonuclease (CVE) as conformational probes. Urea-treated and renatured 5S RNA co-migrate on non-denaturing gels, but exhibit distinct differences in their nuclease cleavage patterns. The most prominent differences in S1 nuclease and CVE accessibility of these conformers are located in region 30-50 and around nucleotides 70 and 90. The third form of 5S RNA with higher electrophoretic mobility was generated by EDTA treatment. The cleavage patterns of this 5S RNA conformer are similar to that characteristic for the renatured 5S RNA. The results demonstrate the difference in secondary structure and possibly different tertiary base-pairing interactions of 5S RNA conformers.     

Caffeine enhancement of digestion of DNA by nuclease S1.

The activity of Aspergillus orzae nuclease S1 on DNA has been investigated under varying pH and metal ion conditions. Nuclease S1 was found to preferentially digest denatured DNA. With native DNA as substrate the enzyme could only digest the DNA when caffeine was added to the reaction mixture. The enzyme was more active in sodium acetate buffer (pH 4.5), than in either standard saline citrate (PH 7.0) or sodium phosphate buffer (pH 6.8). Caffeine was also found to affect the thermal stability of DNA, resulting in a melting profile characterized by two transitions. The first transition (poorly defined) was below the normal melting temperature of the DNA, while the next transition was at the normal melting temperature of the DNA, while the next transition was at the normal melting temperature of the DNA. The susceptibility of caffeine-treated DNA to nuclease digestion seems to be a result of the local unwinding that caffeine causes in the regions of DNA that melt in the first transition. This selective destabilization presumably sensitizes the unwound regions to nuclease hydrolysis. The hydrolysates of the DNA digested by nuclease S1 were subjected first to ion exchange chromatography followed by paper chromatography. The results from this partial characterization of the digestion products showed that they contain mononucleotides as well as oligonucleotides of varying lengths. The base composition of the mononucleotide digests suggests that caffeine has greater preference for interacting with A-T base-pairs in DNA.     

Conformation of methylated sequences in HeLa cell 18-S ribosomal RNA: nuclease S1 as a probe

18-S rRNA from HeLa cells was digested with nuclease S1. Under the conditions employed 15% of the total nucleotides and some 50% of the methylated nucleotides were released as low-molecular-weight products. The material which was precipitable by 70% ethanol after nuclease S1 digestion was subjected to further digestion by combined T1 plus pancreatic ribonucleases or by T1 ribonuclease alone, and fingerprints were prepared. It was found that the four sites which are modified late during ribosome maturation, and which contain base modifications, were all accessible to nuclease S1. By contrast fewer than one-half of the sites which are modified early during ribosome maturation, and which contain 2'-O-methyl groups, were accessible to nuclease S1; the remainder were protected, presumably by secondary or tertiary interactions within 18-S rRNA.     

The effect of tRNA binding on the structure of 5 S RNA in Escherichia coli. A chemical modification study

The structure of 5 S RNA within the 70 S ribosome from Escherichia coli was studied using the chemical reagent kethoxal (alpha-keto-beta-ethoxybutyraldehyde) to modify accessible guanosines. The modification pattern of 5 S RNA from free 70 S ribosomes was compared with that of poly(U) programmed ribosomes where tRNA had been bound to both the A- and P-sites. Binding to the ribosomal A-site was achieved enzymatically using the elongation factor Tu and GTP in the presence of deacylated tRNA which blocks the ribosomal P-site. Modified guanosines were identified after partial RNase T1 hydrolysis and separation of the hydrolysis products on sequencing gels. Binding of tRNA to the ribosome leads to a strong protection of 5 S RNA guanosine G-41 and to some degree G-44 from kethoxal modification. The limited RNase T1 hydrolysis pattern provides evidence for the existence of a 5 S RNA conformation different from the known 5 S RNA A- and B-forms which are characterized by their gel electrophoretic mobility. The importance of 5 S RNA for the binding of tRNA to the ribosome is discussed.     

Investigation of the tertiary folding of Escherichia coli ribosomal RNA by intra-RNA cross-linking in vivo

"In vivo" cross-links were introduced into ribosomal RNA by direct ultraviolet irradiation of intact Escherichia coli cells, during growth in a 32P-labelled medium. Ribosomes were isolated from the irradiated cultures, dissociated into subunits and subjected to partial digestion with cobra venom nuclease. The intra-RNA cross-linked fragments were separated by two-dimensional gel electrophoresis and the sites of cross-linking determined, using our published methodology. A comparison with the data previously obtained by this procedure, after irradiation of isolated 30 S and 50 S subunits, showed that in the case of the 50 S subunit nine out of the ten previous cross-links in the 23 S RNA could be identified in the "in vivo" experiments, and correspondingly in the 30 S subunit five out of the six previous cross-links in the 16 S RNA were identified. Some new cross-links were found, as well as two cross-links in the 16 S RNA, which had hitherto only been observed after partial digestion of irradiated 30 S subunits with ribonuclease T1. The relevance of these data to the tertiary folding of the rRNA in situ is discussed, with particular reference to the work of other authors, in which "naked" RNA was used as the substrate for cross-linking and model-building studies.     

The conserved 5 S rRNA complement to tRNA is not required for translation of natural mRNA

We have tested a putative base-paired interaction between the conserved GT psi C sequence of tRNA and the conserved GAAC47 sequence of 5 S ribosomal RNA by in vitro protein synthesis using ribosomes containing deletions in this region of 5 S rRNA. Ribosomes reconstituted with 5 S rRNA possessing a single break between residues 41 and 42, deletion of residues 42-46, or deletion of residues 42-52 were tested for their ability to translate phage MS2 RNA. Initiator tRNA binding, aminoacyl-tRNA binding, ppGpp synthesis, and miscoding were also tested. All of the measured functions could be carried out by ribosomes carrying the deleted 5 S rRNAs. The sizes and relative amounts of the polypeptides synthesized by MS2 RNA-programmed ribosomes were identical whether or not the 5 S RNA contained deletions. Aminoacyl-tRNA binding and miscoding were essentially unaffected. Significant reduction in ApUpG (but not poly(A,U,G) or MS2 RNA)-directed fMet-tRNA binding and ppGpp synthesis were observed, particularly in the case of the larger (residues 42-52) deletion. We conclude that if tRNA and 5 S rRNA interact in this fashion, it is not an obligatory step in protein synthesis.     

Isolation of Euglena gracilis chloroplast 5S ribosomal RNA and mapping the 5S rRNA gene on chloroplast DNA.

Ribosomal RNA (5S) from Euglena gracilis chloroplasts was isolated by preparative electrophoresis, labeled in vitro with 125I, and hybridized to restriction nuclease fragments from chloroplast DNA or cloned chloroplast DNA segments. Euglena chloroplast 5S rRNA is encoded in the chloroplast genome. The coding region of 5S rRNA has been positioned within the 5.6 kilobase pair (kbp) repeat which also codes for 16S and 23S rRNA. There are three 5S rRNA genes on the 130-kbp genome. The order of RNAs within a single repeat is 16S-23S-5S. The organization and size of the Euglena chloroplast ribosomal repeat is very similar to the ribosomal RNA operons of Escherichia coli.     

Concerning the thermal stability of E. coli 23S ribosomal RNA

Total RNA prepared from E. coli by several extraction procedures behaves as a mixture of covalently continuous heat stable 23S, 16S and 4-5S components. 16S rRNA remains heat stable after isolation from such preparations, whereas isolated 23S rRNA is heat labile but becomes heat stable after EDTA treatment. This and other evidence leads to the conclusion that heat lability of purified 23S rRNA is due, not to nuclease contamination of the type observed in earlier studies of the stability of this RNA, but to polyvalent cation catalyzed temperature-dependent scission of phosphodiester bonds. Heat stability of 23S rRNA in total RNA is due to the presence in these preparations of a contaminant which appears to act as a chelator of polyvalent cations. This material is similar or identical to the pyrogenic E. coli lipopolysaccharide described by Westphal and coll.     

Terminally directed hydrolysis of duplex ribonucleic acid catalyzed by a species of the BAL 31 nuclease from Alteromonas espejiana

The extracellular nuclease activities of Alteromonas espejiana sp. BAL 31 are mediated by at least two distinct protein species that differ in molecular weights and catalytic properties. The two species that have been purified to homogeneity and characterized, the "fast" (F) and "slow" (S) enzymes, both possess an exonuclease activity that shortens both strands of duplex DNA, with the F nuclease displaying a much greater (approximately 19-fold) turnover number for this degradation than the S species. In the present article, it is shown that the F species also mediates the terminally directed hydrolysis of a linear duplex RNA, gradually shortening molecules of this substrate through a mechanism that results in the removal of nucleotides from both the 3' and the 5' ends. This degradation proceeds with very infrequent introduction of scissions away from the termini as demonstrated by gel electrophoretic examination of the products of partial degradation, both in duplex form and after denaturation by reaction with CH3HgOH, and by electron microscopic characterization of duplex partially degraded molecules. The apparent Michaelis constant and turnover number have been determined. At equimolar enzyme concentrations in the limit of high substrate concentration, the F nuclease will degrade duplex RNA at a rate 0.021 +/- 0.010 (S.D.) times that for a duplex DNA of comparable guanine + cytosine content. The S species, by contrast, shows very little activity against the duplex RNA substrate relative to that of the F enzyme.     

S1 nuclease as a probe of yeast ribosomal 5 S RNA conformation.

5 S RNA was isolated from Saccharomyces cerevisiae grown in the presence of 32P-phosphate and digested with nuclease S1, a single-strand specific nuclease. Two different procedures were employed to determine the sites of attack on the RNA. First, 5 S RNA was isolated from nuclease S1 digests, digested to completion with ribonuclease T1, and then 'fingerprinted' by two-dimensional electrophoresis. Quantitation of each of the characteristic RNAase T1-derived oligonucleotides was employed to determine the relative susceptibility of various regions of the molecule to nuclease S1. A second procedure to define nuclease S1-susceptible sites in the molecule employed polyacrylamide gel electrophoretic fractionation of nuclease S1 digests followed by identification of the nucleotide sequences of the released RNA fragments. Both procedures showed that the region of the molecule between residues 9 and 60 was most susceptible to nuclease S1, with preferential cleavage occurring between residues 12-25 and 50-60. These results are discussed in relation to a proposed model for the secondary structure of yeast 5 S RNA.