A new species of virus-coded low molecular weight RNA from cells infected with adenovirus type 2

A virus-coded low molecular weight RNA (5.2S), which migrates slightly faster on polyacrylamide gels than the well characterized adenovirus-specific 5.5S RNA, has been isolated from cells infected with adenovirus type 2. Hybridization-competition experiments and RNA fingerprints indicate that the two virus-associated (VA) RNAs differ in their primary structures. The gene for 5.2S RNA is located to the right of the gene for 5.5S RNA, on the I strand of a DNA segment which extends between positions 30.3 and 32.2 on the map of adenovirus type 2 DNA.Both 5.5S and 5.2S RNA can be detected early after infection and also in the presence of cytosine-arabinoside or cycloheximide. After the onset of viral DNA replication, the synthesis of 5.2S RNA levels off, whereas 5.5S RNA is synthesized in increasing amounts. Both 5.2S and 5.5S RNAs are synthesized in isolated nuclei by an enzyme which resembles RNA polymerase III in its sensitivity to α-amanitin. In isolated nuclei, both RNA species are labeled with β-³²P-labeled GTP, which suggests that they are initiated at separate promoter sites.     

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.     

Covalent linkage between ribonucleic Acid primer and deoxyribonucleic Acid product of the avian myeloblastosis virus deoxyribonucleic Acid polymerase

Initiation of deoxyribonucleic acid (DNA) synthesis by the avian myeloblastosis virus DNA polymerase was previously suggested to involve a ribonucleic acid (RNA) primer, the initial product being a DNA molecule joined by a phosphodiester bond to the RNA primer. The existence and nature of such an RNA-DNA joint was investigated by assaying for transfer of a ³²P atom from an α-³²P-deoxyribonucleotide to a 2′(3′)-ribonucleotide after alkaline hydrolysis of the polymerase product. Such a transfer was observed, but only from α-³²P-deoxyadenosine triphosphate and only to 2′(3′)-adenosine monophosphate. This same transfer was observed in both the endogenous DNA polymerase reaction of purified virions and the reconstructed reaction of purified DNA polymerase plus purified 60 to 70S viral RNA. These results indicate a high level of specificity for the initiation process and support the idea of a low-molecular-weight initiator RNA as part of the 60 to 70S RNA complex.     

Characterization of the DNA and structural proteins of entomopoxviruses from Melanoplus sanguinipes,Arphia conspirsa, and Phoetaliotes nebrascensis (Orthoptera)

Entomopoxvirus (EPV) occlusion bodies were isolated from virus infected nymphs of the grasshoppers Melanoplus sanguinipes, Arphia conspirsa, and Phoetaliotes nebrascensis. Separation of the viral structural proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis gave unique protein patterns for each of the three viruses. An occlusion body protein of approximately 100,000 MW was isolated from each virus. Cleavage of viral DNA with HinddIII and BamHI restriction endonucleases and separation of the fragments by agarose gel electrophoresis gave different DNA fragment patterns for each of the three entomopoxviruses. Molecular weight estimates of 120 × 10⁶ for M. sanguinipes EPV DNA, 129 × 10⁶ for A. conspirsa EPV DNA, and 125 × 10⁶ for P. nebrascensis EPV DNA were calculated from the sizes of the viral DNA fragments. Approximately 55% base sequence homology was detected by Southern hybridization of α-³²P-labeledM. sanguinipes EPV DNA with P. nebrascensis DNA. No base sequence homology was detected by Southern hybridization of labeled M. sanguinipes EPV DNA to Othnonius batesi EPV DNA (Coleoptera), Amsacta moorei EPV DNA (Lepidoptera), Euxoa auxiliaris EPV DNA (Lepidoptera), and vaccinia virus DNA fragments.     

Detection of DNA base sequence homology between entomopoxviruses isolated from lepidoptera and orthoptera

The extent of DNA base sequence homology between entomopoxviruses (EPVs) from Lepidoptera, Orthoptera, and the vertebrate poxvirus Vaccinia was investigated by DNA-DNA hybridization. α-³²P-Labeled DNA from Amsacta moorei EPV, Melanoplus sanguinipes EPV, and Vaccinia virus strain WR was hybridized with the DNA from six different entomopoxvirus isolates. Based on the thermal denaturation temperature of hybrid DNA molecules, approximately 54% base sequence homology was detected between Amsacta moorei and Euxoa auxiliaris EPV DNAs. Extensive DNA hybridization was detected between α-³²P-labeled Melanoplus sanguinipes EPV DNA and DNA from Arphia conspirsa and Phoetaliotes nebrascensis entomopoxviruses. No base sequence homology was detected between vaccinia DNA and DNA from any of the entomopoxvirus isolates used in this study.     

Sequence and symmetry in ribosome binding sites of bacteriophage f1 RNA

RNA was synthesized in vitro from α-³²P-labeled ribonucleoside triphosphates with Escherichia coli RNA polymerase from covalently closed, circular, double-stranded DNA isolated from cells infected with bacteriophage f1. This RNA, which serves as an efficient message in vitro, was bound to ribosomes and the initiation complexes were digested with bovine pancreatic ribonuclease. Ribosome-protected fragments were isolated, purified and separated by two-dimensional analysis using electrophoresis and homochromatography. Sequence analysis, taking advantage of the ability to determine nearest neighbors, was done by conventional techniques.The sequences of the ribosome-protected fragments were found to fall into three classes. One sequence corresponds to the amino-terminal region of the protein product of f1 gene V, a DNA binding protein. It is proposed that a second sequence may correspond to the amino-terminal region of a precursor to the major coat protein. No assignment has yet been made for the third sequence.Comparisons are made between these three sequences and others that are available, both in terms of sequence features that have been pointed out earlier, and in terms of certain considerations of symmetry and syntax² prominent in these binding site sequences that have not been discussed before.     

Initiator RNA of discontinuous DNA synthesis in human lymphocytes

A short RNA covalently associated with nascent DNA has been isolated after synthesis in vitro with labeled ribonucleoside triphosphates and the removal of DNA by DNAase digestion. The RNA migrates in polyacrylamide gels or chromatographs on DEAE-Sephadex columns as a relatively discrete oligonucleotide 8–11 nucleotides in length. The RNA is associated primarily with nascent DNA with stoichiometry of approximately one per DNA chain. The RNA has a triphosphate group at the 5′ end and 2 or 3 deoxynucleotide residues at the 3′ end that are not removed by DNAase. These results further support a role for the RNA as an initiator of discontinuous DNA synthesis. Examination of sequences present at the 3′ end of the RNA using RNAase to effect transfer of ³²PO₄ from ³²P-labeled DNA to covalently attached RNA indicates that a diverse, rather than unique, set of sequences are present in the RNA.     

Viral DNA in transformed cells: II. A study of the sequences of adenovirus 2 DNA in nine lines of transformed rat cells using specific fragments of the viral genome

³²P-labeled adenovirus 2 DNA was treated with restricting endonuclease from Escherichia coli strain RY-13 (Yoshimori, 1972) (EcoRI) or restricting endonuclease from Hemophilus parainfluenzae (Hpa I) and the resulting fragments of DNA were separated by gel electrophoresis. The kinetics of renaturation of each of the fragments and of complete adenovirus 2 DNA were measured in the presence of DNA extracted from nine lines of adenovirus 2-transformed rat cells and from control cells. Six of the transformed cell lines contained viral DNA sequences homologous to two of the seven Hpa I⁴ fragments and to part of one of the six EcoRI fragments. From the order of the fragments formed by EcoRI and Hpa I on the adenovirus 2 map we conclude that these cell lines contain only the segment of viral DNA that stretches from the left-hand end to a point about 14% along the viral genome. Thus, any viral function expressed in transformed cells must be coded by this small section of viral DNA. The three remaining lines of adenovirus 2-transformed rat cells are more complicated and contain not only the sequences from the left-hand end of the viral DNA, but also other segments of the viral genome. However, no adenovirus 2-transformed rat cell contained DNA sequences homologous to the complete viral genome.     

Viral DNA in transformed cells: I. A study of the sequences of adenovirus 2 DNA in a line of transformed rat cells using specific fragments of the viral genome

³²P-labeled adenovirus 2 DNA was treated with restricting endonuclease isolated from Escherichia coli strain RY-13 (Yoshimori, 1971) and the resulting six fragments were separated by electrophoresis through polyacrylamide-agarose gels. The kinetics of renaturation of each of the fragments and of complete adenovirus 2 DNA were measured in the presence of DNA extracted from a line of transformed rat cells and from control cells. The entire sequences of two of the fragments and part of the sequence of a third fragment were not detectable in the transformed cell DNA. Thus the line of adenovirus 2-transformed rat cells contains sequences homologous to only about 46% of the viral DNA. From the order of the fragments, formed by this restricting endonuclease on the adenovirus 2 map, it seems that the viral sequences that are absent from transformed cells form one continuous segment located in the center of the viral genome.     

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.     

CXII. Total synthesis of the structural gene for an alanine transfer RNA from yeast. Enzymic joining of the chemically synthesized polydeoxynucleotides to form the DNA duplex representing nucleotide sequence 1 to 20

The DNA duplex (designated [A]) corresponding to the nucleotides 1 to 20 of the major yeast alanine transfer RNA (Fig. 1) has been synthesized. The first step involved the T4 ligase-catalyzed joining of d-(5′-³²P)-C-C-G-G-A-A-T-C (segment 4, Fig. 1) to the dodecanucleotide, d-(5′-OH)-T-G-G-T-G-G-A-C-G-A-G-T (segment 1, Fig. 1), in the presence of the complementary decanucleotide d-(5′-OH)-C-C-G-G-A-C-T-C-G-T (segment 3, Fig. 1). The resulting icosanucleotide, d-(5′-OH)-T-G-G-T-G-G-A-C-G-A-G-T-C-C-G-G-A-A-T-C, was isolated free from the decanucleotide (segment 3). The synthesis of [A] was then completed by the ligase-catalyzed joining of 5′-³²P or ³³P-labeled hexanucleotide d-(5′-P)-C-C-A-C-C-A (segment 2) to the 5′-³²P or ³³P-labeled decanucleotide, d-(5′-P)-C-C-G-G-A-C-T-C-G-T (segment 3), in the presence of the above icosanucleotide.     

Isolation and mapping of ribosomal RNA genes of Caulobacter crescentus

Ribosomal DNA fragments of 1.0, 3.4, 3.7 and 6.1 kb² produced by EcoRI digestion of the Caulobacter crescentus genome were identified by hybridization to a labeled ribosomal RNA probe. These genomic sequences were further characterized by the isolation of 13 hybrid λ Charon 4 phages with rDNA inserts, and two of the recombinant phages, Ch4Cc773 and Ch4Cc1880, were examined extensively. The Cc773 insert contains EcoRI fragments of 1.0 kb, 3.4 kb and 3.7 kb and the Cc1880 insert contains EcoRI fragments of 1.0 kb, 3.4 kb and 6.1 kb that hybridized to ³²P-labeled rRNA. Thus, the two clones contain different DNA inserts which together account for all of the rDNA fragments detected in digests of the C. crescentus genome. Hybridization with isolated transfer RNA and individual rRNA species indicated that the arrangement of genes in both units is 16 S-spacer tRNA(s)-23 S-5 S, tRNA(s). Homology between the DNA inserts is largely restricted to the rRNA coding regions, which suggests that the two rDNA units are located in different regions of the chromosome. Results of quantitative hybridization experiments are most consistent with a single Cc1880 and Cc773 unit per genome equivalent of 2.7 × 10⁹ daltons. The relatively simple organization of rDNA sequences in the C. crescentus chromosome compared to Escherichia coli is discussed.     

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.     

Purification of globin messenger RNA from dimethylsulfoxide-induced friend cells and detection of a putative globin messenger RNA precursor

Procedures are described that permit the detection and isolation of a specific messenger RNA as well as its precursor from total cell extracts. DNA complementary to the mRNA was elongated by the addition of dCMP residues and annealed with labeled cell RNA. The elongated DNA with RNA hybridized to it was isolated by chromatography on a poly(I)-Sephadex column. The method was used to isolate ³²P-labeled globin mRNA from labeled Friend cells, a mouse erythroleukaemic cell line, induced with dimethylsulfoxide to synthesize hemoglobin. ³²P-labeled globin mRNA isolated by this procedure was estimated to be 80% pure by hybridization analysis and sedimented as a single peak at 10 S. Partial sequences were determined for 16 oligonucleotides derived from the purified ³²P-labeled globin mRNA by RNAase T₁ digestion. The partial sequences for nine oligonucleotides corresponded to those predicted from the amino acid sequences of α and β globin; the other oligonucleotides were presumably derived from non-translated regions.In order to detect a possible precursor to globin mRNA, RNA from induced Friend cells pulse-labeled with [³²P]phosphate for 20 minutes was centrifuged through a sucrose gradient and the resulting fractions were analyzed for globinspecific sequences. Two peaks of globin-specific RNA were detected, a larger one at 10 S, the position of mature globin mRNA, and a smaller one at 15 S.     

Labeling deoxyribonucleic acid to high specific activity in vitro by nick translation with DNA polymerase I

Circular (e.g. simian virus 40) and linear (e.g. λ phage) DNAs have been labeled to high specific radioactivities (>10⁸ cts/min per μg) in vitro using deoxynucleoside [α-³²P]triphosphates (100 to 250 Ci/mmol) as substrates and the nick translation activity of Escherichia coli DNA polymerase I. The reaction product yields single-stranded fragments about 400 nucleotides long following denaturation. Because restriction fragments derived from different regions of the nick-translated DNA have nearly the same specific radioactivity (cts/min per 10[su3] bases), we infer that nicks are introduced, and nick translation is initiated, with equal probability within all internal regions of the DNA. Such labeled DNAs (and restriction endonuclease fragments derived from them) are useful probes for detecting rare homologous sequences by in situ hybridization and reassociation kinetic analysis.