Characterization of RNA synthesized in isolated nuclei of herpes simplex virus type 1-infected KB cells.

Nuclei isolated from herpes simplex virus (HSV)-infected KB cells actively synthesize HSV RNA in vitro; the RNA can be hybridized with HSV DNA or nuclear RNA from HSV-infected cells. Nascent RNA molecules labeled in vivo with 32PO4 were elongated, utilizing the nuclear system to incorporate Hg-CTP at their 3' ends, and then isolated on an affinity column. Hybridization of isolated nascent RNA molecules showed that greater than 50% of them were HSV specific and that more than 25% were self-complementary.     

Mechanism of DNA chain growth: XV. RNA-linked nascent DNA pieces in Escherichia coli strains assayed with spleen exonuclease

A new method for the detection and assay of RNA-linked nascent DNA pieces has been developed. The method relies on selective degradation by spleen exonuclease of radioactive 5′-OH terminated DNA produced from the pulse-labelled nascent pieces upon alkaline hydrolysis. Analysis with this method in wild type Escherichia coli has shown relatively high proportions of the RNA-linked molecules after shorter pulses and in the smaller pieces, supporting the transient nature of the RNA attachment to the nascent pieces. The RNA-linked nascent DNA pieces are accumulated by both E. coli polAex1 (defective in 5′ → 3′ exonuclease of DNA polymerase I) and E. coli polA12 and polA1 (defective in polymerase of DNA polymerase I), suggesting the requirement of the concerted action of both 5′ → 3′ exonuclease and polymerase of DNA polymerase I for the removal of the RNA attached to the nascent pieces. Most of the nascent DNA pieces accumulated by E. coli ligts7 (defective in DNA ligase) are not linked to RNA, as expected from the direct role of DNA ligase in joining of the pieces. The analysis also has shown that a large portion of the nascent DNA pieces present in the cell under the normal steady-state conditions are not linked to RNA and that the level of the RNA-free DNA pieces is also increased in polA mutants. These findings suggest that the removal of RNA from the nascent pieces is a relatively rapid process and the joining reaction is a rate-limiting step that requires the concurrent action of DNA polymerase and DNA ligase.     

Rat liver chromatin. Fractionation into eu- and heterochromatin with localization of ribosomal genes.

Purified, normal rat liver chromatin was sheared under controlled conditions in a Virtis “60” homogenizer and then separated into template-active (euchromatin) and template-inactive (heterochromatin) fractions by glycerol gradient centrifugation. The euchromatin portions of the glycerol gradients possessed greater than 90% of the in vitro template activity when estimated with Escherichia coli RNA polymerase and contained more than 90% of the nascent RNA formed in vivo. Inhibitor studies performed in vivo indicated that the leading edge of the heterochromatin portion of the glycerol gradients contains the genes coding for ribosomal RNA. Recentrifugation of putative eu- and heterochromatin fractions demonstrated that the isolation procedure produces fractions which are distinct and are characterized by little or no cross contamination. The data suggest that controlled shearing in conjunction with gradient centrifugation provides a means of fractionating with great fidelity the transcribable portions of the rat liver genome.     

RNA primers in Simian virus 40 DNA replication. II. Distribution of 5' terminal oligoribonucleotides in nascent DNA.

A cell-free simian virus 40 (SV40) DNA replication system served to study the role of RNA in the initiation of nascent DNA chains of less than 200 nucleotides (Okazaki pieces). RNA-DNA covalent linkages were found to copurify with SV40 replicating DNA. These linkages were identified by transfer of a fraction of the ³²P from the 5′ position of a deoxyribonucleotide to 2′(3′)rNMPs upon either alkaline hydrolysis or RNAase T₂ digestion of SV40 replicating [³²P]DNA. Alkaline hydrolysis also exposed 5′ terminal hydroxyl groups in the nascent DNA which were detected as nucleosides after digestion with P1 nuclease. The RNA-DNA covalent linkages resulted from a population of Okazaki pieces containing uniquely sized oligoribonucleotides covalently attached to their 5′ termini (RNA primers). The density of a portion of the Okazaki pieces in potassium iodide gradients corresponded to a content of 90% DNA and 10% RNA, while the remaining Okazaki pieces appeared to contain only DNA. Incubation of Okazaki pieces with a defined length in the presence of either RNAase T₂ or potassium hydroxide converted about one-third to one-half of them intto a second well defined group of DNA chains of greater electrophoretic mobili y in polyacrylamide gels. The increased mobility corresponded to the removalof at least seven-residues. Since alkaline hydrolysis of similar Okazaki pieces revealed that one-third to one-half of them contained rN-³²P-dN linkages, the oligoribonucleotides must be covalently attached to the 5′ ends of nascent DNA chains. Although the significance of two populations of Okazaki pieces, one with and one without RNA primers, is imperfectly understood, a sizable fraction of nascent DNA chains clearly contained RNA primers.Neither the length of the RNA primer nor the number of RNA primers per DNA chain changed significantly with increasing length of Okazaki pieces. Since the frequency of RNA-DNA junctions found in nascent DNA chains greater than 400 nucleotides was similar to that of Okazaki pieces, the complete excision of RNA primers appears to occur after Okazaki pieces are joined to the 5′ end of growing daughter strands.³²P-label transfer analysis of Okazaki pieces recovered from hybrids with isolated HindII + III restriction fragments of SV40 DNA revealed a uniform distribution of rN-P-dN sequences around the replicating DNA molecule. Therefore, most, if not all, RNA primers serve to initiate Okazaki pieces rather than to initiate DNA replication at the origin of the genome. Moreover, the positions of RNA primers are not determined by a specific set of nucleotide sequences.     

Initiator RNA of nascent DNA from animal cells.

Nascent DNA synthesized by intact cells has been examined for the presence of RNA that may function as a primer in the discontinuous synthesis of DNA. A low molecular weight fraction that contains nascent DNA was isolated from a human lymphoblastoid cell line in logarithmic growth. After labeling the 5′ ends with bacteriophage T4 polynucleotide kinase and [γ-³²P]ATP, and digestion of the DNA with DNAase, a DNAase-resistant oligonucleotide was isolated. This fragment consisted of approximately 9 ribonucleotide residues, with 5′ terminal purines ($\text{A}\text{G}\text{=}\text{3·5}\text{1}$), plus one to three 3′ terminal deoxynucleotides resulting from incomplete removal by DNAase. Approximately 10% of short nascent DNA chains contained the nonanucleotide molecule. An additional 20% of the nascent DNA contained ribooligomers shorter than 9 residues, with 5′ termini substantially increased in pyrimidines, which may result from degradation of the nonanucleotide. These results extend previous studies that demonstrated a similar ribooligonucleotide present at the 5′ end of most or all short nascent DNA chains synthesized in broken cell systems. Together with the results obtained by Reichard and co-workers (Reichard et al., 1974) with polyoma virus, the data support a mechanism by which a short initiator RNA serves as primer for discontinuously synthesized DNA in animal cells.     

Characterization of the ribosomal RNA precursor in Ilyanassa

Ilyanassa embryos synthesized a high molecular weight, rapidly-labeled RNA species that, as time progressed, diminished in proportion to increasing amounts of nascent ribosomal RNA. We tentatively identify this rapidly-labeled RNA species as the ribosomal RNA precursor. Its molecular weight, determined by acrylamide gel electrophoresis, was 2.4–2.5 × 10⁶; a molecule of intermediate size (1.8 × 10⁶ Daltons) was also detected.     

Nascent ribosomal and messenger RNA in DNA-membrane-complexes of Escherichia coli

Summary From Escherichia coli, DNA-membrane-complexes have been isolated which contain about 40% of the ribosomes, about 95% of the DNA and nearly all of the nascent RNA. The kinetic data on pulse labeled RNA show an average time of turnover of about 60 sec both for nascent messenger- and nascent ribosomal RNA. A proportion of the polysomes with nascent messenger RNA as well as most of the nascent ribosomal RNA is found in association with membranes, as has been shown by subfractionations of the DNA-membrane-complex involving treatment with DNase and desoxycholate. In this early transient stage, ribosomal precursor RNA already acquires some ribosomal proteins, as has been shown by arginine pulse label. Data on partial release of DNA from the DNA-membrane-complex by treatment with extremely low doses of DNase indicate that messenger RNA synthesis occurs in clusters on the DNA.The results support models in which, at any given time, RNA synthesis proceeds mainly in sections of the DNA close to the membrane. Thereby the DNA is linked to the membrane via nascent RNA contained in ribosomal precursors as well as via nascent messenger RNA on membrane-bound polysomes.     

Cleavage of the N-terminal formylmethionine residue from a bacteriophage coat protein in vitro

Studies were made of the N-terminal formylmethionine content of nascent and complete coat protein of bacteriophage Qβ synthesized in an Escherichia coli cell-free system. Under normal conditions of cell-free protein synthesis the formylmethionine residue was retained by all the nascent chains but by only about 50% of the completed coat protein molecules. If 2-mercaptoethanol was omitted from the cell-free system, the formylmethionine residue was cleaved during the course of peptide chain elongation. All nascent peptides which contained fewer than 40±5 amino acids retained the formylmethionine residue. Thereafter, the proportion of nascent peptides lacking the residue increased with peptide length to about 70% for nearly full length nascent peptides and complete released coat protein molecules.