Modified sequences in yeast ribosomal RNA

26S and 17S yeast ribosomal RNA were digested with T ₁ plus pancreatic ribonuclease and the products were fractionated by two-dimensional electrophoresis. Besides the expected standard products (type (Ap) _n Np, where N is C, U or G) several non-standard products were found to be present in the digests. The latter products include methylated oligonucleotides and pseudouridylic acid (p)-containing fragments. The primary structure and molar frequency of these modified products were determined. They appeared to be present in approximately integral molar amounts. Several of these oligonucleotides contain more than one modification. The total number of p-residues in 26S and 17S yeast rRNA was estimated to be about 32 and 14, respectively.     

Fingerprinting nonradioactive ribonucleic acid with the aid of polynucleotide phosphorylase

We describe a method for obtaining radioactive fingerprints from nonradioactive ribonucleic acid. Fragments derived by T1 ribonuclease digestion of RNA are dephosphorylated with bacterial alkaline phosphatase. When these fragments are used as primers for the reaction of primer dependent polynucleotide phosphorylase with [α-³²P]GDP in the presence of T1 ribonuclease the 3′-hydroxyl group of each fragment becomes phosphorylated. The degree of phosphorylation is reasonably uniform. The method has been applied to T1 ribonuclease digests of Escherichia coli tRNA^Met_f; the oligonucleotides were further analyzed by spleen phosphodiesterase digestion. In a similar manner fingerprints of pancreatic ribonuclease digests of RNA can be obtained, when [α-³²P]UDP, polynucleotide phosphorylase and pancreatic ribonuclease are used.     

Purification and properties of bacteriophage T4-induced RNA ligase

RNA ligase has been extensively purified by a new procedure in high yield from T4-infected Escherichia coli. The enzyme consists of a single polypeptide chain of molecular weight 47,000. It catalyzes the formation of a phosphodiester bond between a 5′-PO₄-terminated oligonucleotide and a 3′-OH terminated oligonucleotide. The purified enzyme catalyzes both the intramolecular formation of single-stranded circles with longer oligonucleotides of the type pAp(Ap)_nA_?OH, where n is about 15 or greater and the intermolecular joining of pAp(Ap)₃A_OH (where the 5′-PO₄-terminated oligonucleotide is short enough to prevent apposition of its 3′ and 5′ ends) to UpUpU_OH when high concentrations of the 3′-OH-terminated acceptor oligonucleotide are present. Preparations of RNA ligase at all stages of purification show an unusual dependence of specific activity of the enzyme on the concentration of enzyme present in the assay. However, when care is taken to determine meaningful specific activities at each step, the ligase is found to be very stable during chromatography on various ion-exchange columns and may be purified by conventional techniques.     

Demonstration of the "5-8 S" ribosomal sequence in HeLa cell ribosomal precursor RNA

HeLa cell “5.8 S” ribosomal RNA was digested with T₁ ribonuclease and the digestion products were characterized. In particular several hexa-, or larger, oligonucleotides were well fractionated by T₁ ribonuclease plus alkaline phosphatase fingerprints. The sequences of these large products were determined. The same large products were identified in fingerprints of “native” 28 S RNA, that is, 28 S RNA to which 5.8 S RNA is attached. The products were demonstrably absent in fingerprints of heat-denatured 28 S RNA, which lacks the 5.8 S fragment. The oligonucleotides were present in fingerprints of 32 S RNA, whether previously heated or not. One of the largest 5.8 S oligonucleotides contains an alkali-stable (2′-O-methylated) dinucleotide, Gm-C. This product was identified in fingerprints of methyl-labelled 45 S RNA. These findings prove that the 5.8 S ribosomal sequence is present within HeLa cell ribosomal precursor RNA. In addition to the methylated nucleotide, two pseudouridylate residues were discovered in HeLa cell 5.8 S RNA.     

Design of antisense oligonucleotides stabilized by locked nucleic acids

The design of antisense oligonucleotides containing locked nucleic acids (LNA) was optimized and compared to intensively studied DNA oligonucleotides, phosphorothioates and 2′-O-methyl gapmers. In contradiction to the literature, a stretch of seven or eight DNA monomers in the center of a chimeric DNA/LNA oligonucleotide is necessary for full activation of RNase H to cleave the target RNA. For 2′-O-methyl gapmers a stretch of six DNA monomers is sufficient to recruit RNase H. Compared to the 18mer DNA the oligonucleotides containing LNA have an increased melting temperature of 1.5–4°C per LNA depending on the positions of the modified residues. 2′-O-methyl nucleotides increase the T_m by only <1°C per modification and the T_m of the phosphorothioate is reduced. The efficiency of an oligonucleotide in supporting RNase H cleavage correlates with its affinity for the target RNA, i.e. LNA > 2′-O-methyl > DNA > phosphorothioate. Three LNAs at each end of the oligonucleotide are sufficient to stabilize the oligonucleotide in human serum 10-fold compared to an unmodified oligodeoxynucleotide (from t_1/2 = ~1.5 h to t_1/2 = ~15 h). These chimeric LNA/DNA oligonucleotides are more stable than isosequential phosphorothioates and 2′-O-methyl gapmers, which have half-lives of 10 and 12 h, respectively.     

Affinity labeling of specific regions of 23 S RNA by reaction of N-bromoacetyl-phenylalanyl-transfer RNA with Escherichia coli ribosomes

Reaction of the affinity-labeling reagent N-bromoacetyl-[¹⁴C]phenylalanyl-tRNA with Escherichia coli ribosomes results in covalent labeling of 23 S ribosomal RNA in addition to the previously reported labeling of ribosomal proteins. The reaction with the 23 S RNA is absolutely dependent on the presence of messenger RNA. Covalent attachment of the affinity label to 23 S RNA was demonstrated by its integrity in strongly dissociating solvents, and the conversion of the labeled material to small oligonucleotides by ribonuclease treatment. After digestion of labeled 23 S RNA with T₁ ribonuclease, the radioactivity is found mainly in two oligonucleotide fragments. These results support models in which both ribosomal RNA and ribosomal protein contribute to the structure of the region of the ribosome surrounding the peptidyl transferase center.     

Enhanced RNA cleavage within bulge-loops by an artificial ribonuclease

Cleavage of phosphodiester bonds by small ribonuclease mimics within different bulge-loops of RNA was investigated. Bulge-loops of different size (1–7 nt) and sequence composition were formed in a 3′ terminal fragment of influenza virus M2 RNA (96 nt) by hybridization of complementary oligodeoxynucleotides. Small bulges (up to 4 nt) were readily formed upon oligonucleotide hybridization, whereas hybridization of the RNA to the oligonucleotides designed to produce larger bulges resulted in formation of several alternative structures. A synthetic ribonuclease mimic displaying Pyr–Pu cleavage specificity cleaved CpA motifs located within bulges faster than similar motifs within the rest of the RNA. In the presence of 10 mM MgCl₂, 75% of the cleavage products resulted from the attack of this motif. Thus, selective RNA cleavage at a single target phosphodiester bond was achieved by using bulge forming oligonucleotides and a small ribonuclease A mimic.     

Hydration of short DNA, RNA and 2'-OMe oligonucleotides determined by osmotic stressing

Studies on hydration are important for better understanding of structure and function of nucleic acids. We compared the hydration of self-complementary DNA, RNA and 2′-O-methyl (2′-OMe) oligonucleotides GCGAAUUCGC, (UA)₆ and (CG)₃ using the osmotic stressing method. The number of water molecules released upon melting of oligonucleotide duplexes, Δn_W, was calculated from the dependence of melting temperature on water activity and the enthalpy, both measured with UV thermal melting experiments. The water activity was changed by addition of ethylene glycol, glycerol and acetamide as small organic co-solutes. The Δn_W was 3–4 for RNA duplexes and 2–3 for DNA and 2′-OMe duplexes. Thus, the RNA duplexes were hydrated more than the DNA and the 2′-OMe oligonucleotide duplexes by approximately one to two water molecules depending on the sequence. Consistent with previous studies, GC base pairs were hydrated more than AU pairs in RNA, whereas in DNA and 2′-OMe oligonucleotides the difference in hydration between these two base pairs was relatively small. Our data suggest that the better hydration of RNA contributes to the increased enthalpic stability of RNA duplexes compared with DNA duplexes.     

A comparison of the 16S ribosomal RNAs from mesophilic and thermophilic bacilli: Some modifications in the sanger method for RNA sequencing

Summary Two modifications in the Sanger two dimensional electrophoretic procedure for RNA analysis are reported. One increases resolution on the primary fingerprint to the point that digests of large RNAs, of the size 1500–3000 nucleotides yield well resolved fingerprint patterns. The other is a novel endonucleolytic procedure that proves useful in determining sequences of the large oligonucleotides produced by T1 ribonuclease.These modifications have been used in determining the catalogs of oligomers produced by T1 ribonuclease digestion of 16S rRNAs from three related organisms,Bacillus subtilis, B.pumilus andB.stearothermophilus. The possible effects of adaptation to a thermophilic niche on ribosomal RNA primary structure and the phylogenetic relatedness of the two mesophilic Bacilli are discussed.This is contribution No.6 in a series on procaryote phylogeny.     

Rapid in vitro labeling procedures for two-dimensional gel fingerprinting

Improvements of existing in vitro procedures for labeling RNA radioactively, and modifications of the two-dimensional polyacrylamide gel electrophoresis system for making RNA fingerprints are described. These improvements are (a) inactivation of phosphatase with nitric acid at pH 2.0 eliminated the phenol-chloroform extraction step during 5′-end labeling with polynucleotide kinase and [γ-³²P]ATP; (b) ZnSO₄ inactivation of RNase T₁ results in a highly efficient procedure for 3′-end labeling with T4 ligase and [5′-³²P]pCp; and (c) a rapid 4-min procedure for variable quantity range of ¹²⁵I and RNA results in a qualitative and quantitative sample for high-molecular weight RNA fingerprinting. Thus, these in vitro procedures become rapid and reproducible when combined with two-dimensional gel electrophoresis which eliminates simultaneously labeled impurities. Each labeling procedure is compared, using tobacco mosaic virus, Brome mosaic virus, and polio RNA. A series of Ap-rich oligonucleotides was discovered in the inner genome of Brome mosaic Virus RNA-3.     

The 5'-terminal sequence of Q 6S RNA

[γ-³²P]GTP-Labeled Qβ 6S RNA yielded only one major radioactive oligonucleotide after digestion with pancreatic ribonuclease. Nearest neighbor analysis of this 5′-oligonucleotide demonstrated that approximately 95% of the molecules terminate with the same sequence, pppGpGpCp. This sequence is the complement of the only major 3′-sequence found in this RNA. Both strands of 6S RNA therefore appear to have identical 3′- and 5′-terminal trinucleotide sequences.     

The nucleotide sequences of some large ribonuclease T1 products from bacteriophage R17 ribonucleic acid

A method of `fingerprinting' high-molecular-weight <sup>32</sup>P-labelled RNA species, using a two-dimensional thin-layer-chromatographic separation of ribonuclease T<sub>1</sub> digestion products, has been applied to RNA from the Escherichia coli bacteriophage R17. The `fingerprinting' technique, besides giving a unique pattern that can be used as a characterization of the RNA, has made it possible to isolate a number of the larger oligonucleotides and to determine their nucleotide sequences.     

2′-modified oligoribonucleotides containing 1,2-diol and aldehyde groups. Synthesis and properties

1,2-Diol-oligoribonucleotides were prepared using fully protected 2??-O-[2-(2,3-dihydroxypropyl)amino-2-oxoethyl]uridine 3??-phosphoramidite. Incorporation of the modified uridine residue into oligonucleotide chains was not shown to significantly affect the thermal stability of RNA-RNA and RNA-DNA duplexes. Periodate oxidation of the 1,2-diol group resulted in reactive 2??-aldehyde oligoribonucleotides. These oligonucleotides were studied for their application in the affinity modification of RNA recognizing proteins with an example of bacterial ribonuclease P.     

Reactive column HPLC: rapid analysis on RPC-5 of oligoadenylates that differ at the 3'-terminus.

Oligoadenylates can be analyzed according to the type of 3′-terminus (A_nA, A_nAp, and A_nA > p, oligoadenylates that have at the 3′-terminus no phosphate, a 2′(3′)-monophosphate, and a 2′,3′-cyclic phosphate respectively) by hplc on RPC-5 support using a novel dual-column technique. The first column separates A_nAp plus A_nA > p from A_nA, and at the start of the second column a layer of bacterial alkaline phosphatase enzyme converts the A_nAp into A_nA. Hence this A_nA emerges separately from the original A_nA and from the A_nA > p. The technique can be used to analyze a three-component mixture for a single chain length or a mixture of A_nAp and A_nA > p of mixed chain lengths (n = 3 to 7). The presence of poly(U) does not interfere with the analysis.     

Sequence determination of 5'-terminal and 3'-terminal T1 oligonucleotides of 18-S ribosomal RNA of a mouse cell line (L 5178 Y).

The 5' and 3'-terminal oligonucleotides of 18-S ribosomal RNA of L 5178 Y (a mouse cell line) obtained after total T1 ribonuclease hydrolysis were isolated by a diagonal procedure. They were localized on the fingerprint of T1-ribonuclease-hydrolysed 18-S RNA. These two oligonucleotides were partially hydrolysed by snake venom and spleen phsophodiesterases and resulting products were fractionated bidimensionally. Their base compositions were determined by total hydrolysis with piperidine or snake venom phosphodiesterase. From these results the following sequences were deduced: pU-A-C-C-U-G for the 5'-terminal oligonucleotide and G-A-U-C-A-U-U-Aoh for the 3'-terminal oligonucleotide. Quantitative studies indicated that these sequences represent at least 70% for the 5' oligonucleotide and 85% for the 3' oligonucleotide of the terminal sequences of the 18-S RNA.     

Specific nucleotide sequences in HeLa cell inverted repeated DNA: enrichment for sequences found in double-stranded regions of heterogeneous nuclear RNA

Inverted repeat DNA was isolated from HeLa cell nuclei and transcribed in vitro with Escherichia coli RNA polymerase in the presence of [alpha-³²P]nucleoside triphosphates. The RNA products were digested with T₁ ribonuclease and subjected to separation in two dimensions. The pattern of the prominent oligonucleotides was almost indistinguishable from that seen when the double-stranded regions from ³²P-labeled HeLa cell heterogeneous nuclear RNA were fingerprinted in a similar manner. The sequences of several of the largest prominent T₁ ribonuclease-generated oligonucleotides were determined and were found to agree with those isolated from the double-stranded heterogeneous nuclear RNA that migrated to the same positions in the fingerprints. The most prominent component of the inverted repeat DNA appears to be sequences that are transcribed into double-stranded regions in heterogeneous nuclear RNA molecules.     

Approaches to sequence analysis of 125I-labeled RNA.

A method is described for the initial steps of sequence analysis of RNase T1-and pancreatic RN-ase-resistant oligonucleotides of RNA containing cytidylate residues labeled in vitro with 125I. In many cases an oligonucleotide sequence can be deduced from a consideration of (i) its relative position in the two-dimensional fingerprint (with DEAE thin layer homochromatographic second dimension), (ii) its electrophoretic mobility on DEAE paper at pH 1.9, and (iii) identification of its products of further enzymatic digestion by comparison with a set of marker oligonucleotides. Additional methods including analysis of oligonucleotides following chemical blocking of uridylate residues with CMCT and analysis of products of incomplete enzymatic digestion are also discussed.     

The 5'-termini of the oligonucleotides from ribonuclease T 1 digested E. coli ribosomes

Oligonucleotides remaining in the 70s $\text{Escherichia}\text{coli}$ ribosomal particles after varying degrees of digestion with ribonuclease T₁ were phosphorylated with polynucleotide kinase in the presence of γ-labeled³²P-ATP. The resulting radioactively labeled RNA molecules were further digested with pancreatic ribonuclease and analyzed by a two-dimensional finger-printing technique. The numbers of labeled oligonucleotides were proportional to the duration of T₁ digestion; most of these oligonucleotides yielded ¹pAp and/or ¹pCp as their 5′-end groups upon alkaline hydrolysis.     

The reactivity of the disulphide bonds of bovine pancreatic ribonuclease with glutathione

1. Bovine pancreatic ribonuclease is not reduced by GSH at near-physiological concentrations and pH. 2. Disruption of the structure of ribonuclease by proteolytic enzymes leads to products that can be reduced by GSH. 3. At higher temperatures the disulphide bonds of ribonuclease are completely reduced by GSH in a coupled system. The T_tr is 51° and this has been found to be lower than the T_tr for the abnormal tyrosine residues under the same conditions.     

Unique nucleotide sequence adjacent to the poly (A) region in yeast RNA

Yeast cells growing in a low phosphate medium were labeled with a pulse of ³²P_i or [³H]adenine and harvested after 15 minutes. Total RNA was extracted and digested with ribonuclease T₁. Poly(A)-rich fragments were isolated from the digest by hybridization to poly(U) impregnated fiberglass filters. Gel filtration showed the fragments to have a uniform chain length of about sixteen. Analysis of the composition gave (A₁₁, C₄, U). Complete pancreatic ribonuclease and partial spleen phosphodiesterase digests gave the sequence of the 5′ end of the fragment as CpApApUp-. Since the fragment was a ribonuclease T₁ product, the data points to a unique sequence of at least five residues, -GpCpApApUp-, adjacent to the poly(A)-rich terminus of pulse-labeled yeast mRNA. The remainder of the poly(A)-rich fragment consists of A residues with a few randomly interspaced C residues. The known specificity of yeast poly(A) polymerase can account for the presence of C residues in poly(A) tracts.