Erratum

RNA polynucleotide kinase has been shown to transfer [γ³²P] from ATP to 5-OH termini of endogenous nuclear RNA. The products of this reaction have been isolated in RNA larger than 125 after in vitro incubation of mouse L cell nuclei. About 20%–30% of these 5′-OH kinase products are polyadenylated. A sizeable fraction of the [γ³²P] label from ATP is also found in internal phosphodiester bonds after 30-minute nuclear incubation in vitro. The possibility of substantial [³²P] recycling via the α position of nucleoside triphosphate was ruled out because: (1) 2mM nucleoside triphosphates in the incubation medium, (2) limited nearestneighbor distribution 3′ and 5′ to the phosphodiester bond compared with that from [α³²P] UTP, (3) different nearest-neighbor distribution for RNA molecules > 12S and 12-3S, (4) relative insensitivity of the [γ³²P] incorporation to α-amanitin as compared with total RNA synthesis, (5) internal [³²P] appearance in RNA > 12S in less than five minutes of incubation, and (6) < 0.03% to 0.6% of the total [³²P] in the α position of nucleoside triphosphates after 30 minutes of incubation. The [γ³²P] incorporation was dependent on high ATP concentration and was insensitive to competition by inorganic phosphate. These results are consistent with the levels of 5′ RNA polynucleotide kinase activity in L cell nuclei and suggest the presence of an RNA ligase that can utilize the termini generated by the 5′-OH RNA kinase in a ligation reaction.     

In vitro polyoma DNA synthesis: Involvement of RNA in discontinuous chain growth

Short fragments of DNA (5 S) isolated by denaturation from polyoma replicative intermediates pulse-labeled in vitro were shown to have RNA covalently attached by three criteria: (1) such fragments were slightly denser than bulk viral DNA. (2) They could be labeled directly with α-³²P-labeled ribotriphosphates. (3) Alkaline hydrolysis of fragments labeled with α-³²P-labeled deoxynucleoside triphosphates showed ³²P transfer to 3′ ribonucleoside monophosphates. Except for a preference of transfer from dC, the link showed little sequence specificity. The data are compatible with the notion that all short fragments in replicating viral DNA are initiated by an RNA primer. This RNA is maximally 30 bases long and is rather short-lived.     

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.     

Evidence for the presence of ribonucleotides at the 5' termini of some DNA molecules isolated from Escherichia coli polAex2.

We have purified a set of small DNA molecules from various strains of exponentially growing Escherichia coli, including E. coli polAex2. This material included very short molecules (2 S), the nascent DNA (“Okazaki fragments”) and some longer molecules. Most of the [³H]thymidine incorporated during a brief period of labeling was found in the 5 S to 15 S Okazaki fragments. There was a large number of the 2 S molecules in the cell. The properties of the 5′ ends of these molecules were investigated using three procedures. (1) The DNA preparation, pulse-labeled with [³H]thymidine, was reacted with polynucleotide kinase and ATP to insure that all 5′ ends were phosphorylated. After subjection of the DNA to alkaline hydrolysis, the proportion of incorporated ³H pulse-label that became susceptible to digestion by spleen exonuclease was determined. In different experiments there was an increment of up to 20% in the amount of pulse-labeled E. coli polAex2 DNA that could be hydrolyzed by the exonuclease after treatment with alkali. (2) As in the preceding protocol, phosphorylation of the 5′ ends was assured by reaction with kinase and ATP; the preparation was then treated with alkali and the number of 5′-OH ends generated that could be labeled with ³²P using [γ-³²P]ATP and kinase in a second reaction was determined. The data indicated that 3 to 30% of the molecules could be labeled after alkali digestion, but not before. (3) The DNA molecules were reacted with kinase and [γ-³²P]ATP after having been exposed previously to alkaline phosphatase. The end-labeled molecules were then subjected to an alkaline hydrolysis and the resulting hydrolysate chromatographed on a polyethyleneimine-cellulose thinlayer plate. Alkali treatment was found to release 2′(3′),5′-ribonucleoside diphosphates from 1 to 30% of the molecules; pAp and pGp predominated. Control experiments showed that these ribonucleotides were covalently linked to the 5′ ends of polydeoxyribonucleotides. Curiously, the smaller the DNA molecule the less likely it was to possess a 5′-terminal ribonucleotide. Very few apparent RNA/DNA molecules were observed in the non-polAex2 strains tested. These observations are in part in agreement with previous reports, and we infer that at least some of the nascent E. coli polAex2 DNA molecules are initiated in vivo with a ribonucleotide primer. The relatively smaller proportion of molecules with apparent 5′-terminal ribonucleotides among the smaller DNA molecules and in strains other than E. coli polAex2 suggests to us that there may exist a mechanism for initiating DNA molecules that does not require an RNA primer.     

Properties of a 110000 molecular weight protein in rat liver hnRNP particles

Particles carrying heterogeneous nuclear RNA (30–40 S-particles) were isolated from rat liver nuclei and the particle proteins separated by sodium dodecylsulfate gel electrophoresis. Some properties of a 110000 molecular weight component (P 110/103) were studied in detail: (i) P 110/103 was labeled to a 4–5 times higher specific activity than the major particle proteins in the presence of [¹⁴C]-amino acidsin vivo. (ii) In nuclei incubated with [³H]- or [³²P]-nicotinamide adenine dinucleotide P 110/103 was labeled presumably by ADP-ribosylation. (iii) A protein with the same molecular weight as P 110/103 and isolated from the nuclear extract by affinity chromatography was phosphorylated in vitro.Abbreviations hnRNA heterogeneous nuclear RNA - hnRNP and mRNP ribonucleoproteins which contain hnRNA respectively mRNA     

RNA sequence determination in the nanogram range by a combination of in vitro labeling procedures.

Recently developed methods which allow one to read RNA sequences directly from polyacrylamide gels do not always provide unequivocal results. A combination of primary and secondary in vitro 5′-labeling, as presented here, is methodically and in its results equivalent to fingerprinting and sequencing techniques developed for in vivo labeled RNA. 5 S RNA was used to demonstrate the applicability and reliability of this combination of postlabeling procedures: 5 μg RNA was partially digested, and the resulting overlapping fragments were 5′-³²P-labeled with T4 phage-induced polynucleotide kinase in vitro. After two-dimensional polyacrylamide gel electrophoresis and carrier-free electrophoretic elution, the labeled long fragments, obtained in the 10-ng range, were completely degraded with RNase T₁ and RNase A, respectively. These digests were again ³²P-phosphorylated with T4 kinase and lead to fingerprints which allowed the deduction of the nucleotide sequences of the corresponding long fragments.     

Oligonucleotide fingerprinting of Hela cell 5 S RNA labeled in vitro with 125I

HeLa cell 5 S ribosomal RNA, labeled in vitro at 40°, 60°, or 70°C with ¹²⁵I, has been digested with RNase T1 and fingerprinted by conventional methods. Regardless of the temperature of iodination, ¹²⁵I was bound (exclusively) to virtually all CMP residues. Characterization of labeled oligonucleotides yielded sequence information consistent with that derived from in vivo labeled RNA.     

Structure of the RNA portion of the RNA-linked DNA pieces in bacteriophage T4-infected Escherichia coli cells.

A method for the isolation of the RNA portion of RNA-linked DNA fragments has been developed. The method capitalizes on the selective degradation of DNA by the 3′ to 5′ exonuclease associated with bacteriophage T4 DNA polymerase. After hydrolysis of the DNA portion, the RNA of RNA-linked DNA is recovered mostly as RNA tipped with a deoxyribomononucleotide and a small fraction as pure RNA. On the other hand, the 5′ ends of RNA-free DNA are recovered mostly as dinucleotides and a small fraction as mononucleotides.Using this method, we have isolated the primer RNA for T4 phage DNA synthesis. Nascent short DNA pieces were isolated from T4 phage-infected Escherichia coli cells and the 5′ ends of the pieces were dephosphorylated and then phosphorylated with polynucleotide kinase and [γ-³²P]ATP. After selective degradation of the DNA portions, [5′-³²P]oligoribonucleotides (up to pentanucleotide) were obtained with covalently bound deoxymononucleotides at their 3′ ends. More than 40% of the oligoribonucleotides isolated were pentanucleotides with pApC at the 5′-terminal dinucleotide. The 5′-terminal nucleotide of the tetraribonucleotides was AMP, but that of the shorter chains was not unique. The pentanucleotide could represent the intact primer RNA for T4 phage DNA synthesis.     

Processing of RNA in Escherichia coli is limited in the absence of ribonuclease III,ribonuclease E and ribonuclease P

A strain of Escherichia coli lacking RNAase III and containing thermolabile RNAase E and RNAase P was labeled with ³²P_i at a non-permissive temperature. RNA molecules were separated by two-dimensional polyacrylamide gel electrophoresis. Most of the small RNA species were isolated and analyzed for the presence of 5′ nucleoside triphosphates. In 16 of the 22 species analyzed a significant number of the individual molecules contained 5′ di or triphosphates. We conclude, therefore, that very little endonucleolytic RNA processing occurs in the absence of the three RNA processing enzymes RNAase III, RNAase E and RNAase P.     

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.     

Topography of 16 S RNA in 30 S subunits and 70 S ribosomes accessibility to cobra venom ribonuclease

A ribonuclease extracted from the venom of the cobra Naja oxiana, which shows an unusual specificity for double-stranded RNA regions, was used to obtain new insight on the topography of Escherichia coli ribosomal 16 S RNA in the 30 S subunit and in the 70 S couple. ³²P-labeled 30 S subunits or reconstituted 70 S tight couples containing ³²P-labeled 16 S RNA have been digested under progressively stronger conditions. The cleavage sites have been precisely localized and the chronology of the hydrolysis process studied.The enzyme cleaves the 16 S RNA within 30 S subunits at 21 different sites, which are not uniformly distributed along the molecule. These results provide valuable information on the 16 S RNA topography and evidence for secondary structure features.The binding of the 50 S subunit markedly reduces the rate of the 16 S RNA hydrolysis and provides protection for several cleavage sites. Four of them are clustered in the 3′-terminal 200 nucleotides of the molecule, one in the middle (at position 772) and one in the 5′ domain (at position 336). Our results provide further evidence that the 3′-terminal and central regions of the RNA chain are close to each other in the ribosome structure and lie at the interface of the two subunits. They also suggest that the 5′ domain is probably not involved exclusively in structure and assembly.     

Size and base composition of RNA segments in complementary strands of supercoiled plasmid ColE1 DNA

Preparations of ColEl plasmid DNA synthesized in the presence of chloramphenicol were separated into samples having gaps resulting from removal of ribonucleotides in one or the other of the complementary DNA strands. These samples were used as templates for repair resynthesis reactions using DNA polymerase of Rous sarcoma virus and α-³²P-labeled deoxyribonucleoside 5′-triphosphates. Reactions involved the incorporation of each labeled nucleotide in the presence of three unlabeled nucleotides, and also the incorporation of all four labeled nucleotides followed by complete digestion and electrophoretic separation of the products. By these two methods the RNA integrated in the light strand of ColEl DNA was found to comprise an average of 38 ribonucleotides with a base composition of 17G, 5A, 8C, and 8U. The RNA segment in the heavy strand consists of an average of 15 ribonucleotides with a base composition of 5G, 2A, 4C, and 4U.     

Sequence analysis of small amounts of nonradioactive oligoribonucleotides containing ribose-methylated nucleosides by a combination of 3H- and 32P-labeling techniques

The oligonucleotides A-G-A-Cm-U and Gm-A-A-Y-A-ψ were used as model compounds to demonstrate how the complete nucleotide sequence of small amounts of nonradioactive oligoribonucleotides (0.2–0.3 nmol) can be derived by a combination of ³H-labeling procedures previously published and a new method for the characterization of 2′-O-methylated nucleosides based on enzymatic ³²P labeling. The newly developed method for the identification of ribose-methylated nucleosides entails ³²P labeling by [γ-³²P]ATP/polynucleotide kinase of the 5′-terminus of a ribonuclease T₂-stable 2′-O-methylated dinucleotide derived from the polyribonucleotide, conversion of the labeled dinucleotide to the ³²P-labeled 2′-O-methylated nucleoside 5′-monophosphate, and identification of the monophosphate by its chromatographic properties on a polyethyleneimine-cellulose thin layer. The novel method is simple, fast, and sensitive and, at present, represents the only way by which ribose-methylated nucleosides can be analyzed in small amounts (0.01 nmol) of nonradioactive oligonculeotides or RNA.     

Cooperative binding of 3'-fragments of transfer ribonucleic acid to the peptidyltransferase center of Escherichia coli ribosomes.

The binding of substrates to the A-site half (A′) and the P-site half (P′) of the peptidyltransferase center was measured by means of equilibrium dialysis. The tRNA fragments C-A-C-C-A-Leu and C-A-C-C-A-(N-acetyl)Leu were used as A′-site and P′-site substrates, respectively. The A′- and P′-substrates bound well to 50 S in contrast to 30 S subunits; significant binding to 23 S and 16 S RNA was also found. The binding of the P′-site substrate to 23 S RNA and 50 S subunits was very similar at various Mg²⁺ and K⁺ concentrations, indicating that the 23 S RNA is probably directly involved in the binding of the 3′-end of the peptidyl-tRNA. Cooperative effects at the peptidyltransferase center were found using chloramphenicol and deacylated tRNA as competitors, which completely inhibited the substrate binding to one site whilst drastically stimulating binding to the other. Chloramphenicol inhibited the binding of the A′-site substrate C-A-C-C-A-Leu, whereas the binding of the corresponding P′-site substrate was stimulated. In contrast, deacylated tRNA blocked the binding of the P′-site substrate, but stimulated the corresponding A′-site binding. Similarly, the trinucleotide C_p,C_pA inhibited binding of the P′-site substrate (showing complete inhibition at 70 μm) whereas binding of the A′-site substrate was slightly stimulated at concentrations below 70 μm.     

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.     

Structure of the linkage between adenovirus DNA and the 55,000 molecular weight terminal protein

The 5′ terminus of each complementary strand of adenovirus DNA isolated from virions is covalently linked to a protein with an apparent molecular weight of 55,000. We have determined the structure of the protein-DNA linkage. The 55,000 M_r protein, linked to a small [³²P]oligonucleotide, was isolated after DNase digestion of uniformly ³²P-labeled adenovirus 5 (Ad5) DNA-protein complex. The protein was digested with trypsin and the resulting [³²P] peptides were analyzed with the following results. (1) Acid hydrolysis released a single phosphorylated amino acid which was identified as O-phosphoserine in four separate electrophoretic or chromatographic systems; (2) treatment with snake venom phosphodiesterase yielded exclusively dAMP, dCMP and dTMP as expected (there are no guanylate residues in the first 25 nucleotides at the 5′ ends of Ad5 DNA); (3) prior treatment of the [³²P]peptide preparation with snake venom phosphodiesterase greatly reduced the yield of O-phosphoserine upon subsequent acid hydrolysis. These results suggest that Ad5 DNA is bound to the terminal protein by a phosphodiester linkage to the β-OH of a serine residue. This conclusion is supported by the finding that the DNA-protein linkage is readily hydrolyzed in alkali. In 50 mm-NaOH at 70 °C the half time for hydrolysis of the linkage is about ten minutes. After incubation of Ad5 DNA under these conditions we were able to label the 5′ termini with ³²P by sequential treatment with alkaline phosphatase and polynucleotide kinase. Digestion of the end-labeled DNA to 5′ mononucleotides yielded [³²P]dCMP. We conclude that the terminal protein is bound to Ad5 DNA by a phosphodiester linkage between the β-OH of a serine residue of the protein and the 5′-OH of the terminal deoxycytidine residue of the DNA.     

Histone mRNAs contain blocked and methylated 5′ terminal sequences but lack methylated nucleosides at internal positions

Histone mRNA, labeled with ³²P or ³H-methionine during the S phase of partially synchronized HeLa cells, was isolated from the polyribosomes and purified as a “9S” component by sucrose gradient sedimentation. We identified two types of 5′ terminals, m⁷G(5′)pppN^mpN and m⁷G(5′)pppN^m-pN^mpN, in which the first methylated nucleoside is 7-methylguanosine, the second is either N⁶,2′-O-dimethyladenosine, 2′-O-methyladenosine, or 2′-O-methylguanosine, and the third is 2′-O-methyluridine, 2′-O-methylcytidine, or 2′-O-methyladenosine. Approximately 1.7% of the ³²P label was present in the 5′ terminal structures. Assuming a similar specific radioactivity for all phosphates, this percentage corresponds to an average of one terminal per 335 nucleotides. Histone mRNA differed from bulk polyadenylylated mRNA of HeLa cells in lacking significant amounts of 2′-O-methyluridine or 2′-O-methylcytidine in the second position of the 5′ terminal oligonucleotide and in lacking N⁶-methyladenosine residues at internal positions.