Analysis of the 5'-termini of nascent DNA chains synthesized in permeable cells of Bacillus subtilis

The nascent DNA synthesized by permeable cells of Bacillus subtilis in the presence of 5'-mercurideoxycytidine triphosphate and 2',3'-dideoxyATP has been isolated and characterized. The newly synthesized DNA was isolated free from other cellular nucleic acids by affinity chromatography on thiol-substituted agarose. The number average chain length of the nascent DNA synthesized in one minute at 25 degrees C was 33 nucleotide residues, due to the chain-terminating action of 2',3'-dideoxyATP. Several lines of evidence indicated that at least 90% of the DNA thus isolated carried a terminally phosphorylated RNA moiety at its 5'-end: (1) the nascent DNA was resistant to exonucleolytic degradation by spleen phosphodiesterase unless first hydrolyzed by strong alkali or ribonuclease; (2) the 5'-termini of nascent DNA could not be phosphorylated by polynucleotide kinase unless first treated with alkaline phosphatase or subjected to hydrolysis by strong alkali or ribonuclease; (3) alkaline hydrolysis of nascent DNA labeled with 32P at the 5'-end released unlabeled DNA with a free 5'-terminus and 32P-labeled ribonucleoside 3',5'-bisphosphates; (4) ribonuclease degradation of similarly labeled material produced an unlabeled DNA-containing polynucleotide fraction and 32P-labeled ribo-oligonucleotides; (5) chromatography on dihydroxyboryl cellulose showed that the RNA moiety lacked a 3'-terminal cis-diol grouping (even after treatment with alkaline phosphatase) unless first subjected to the 3'-exonucleolytic action of bacteriophage T4 DNA polymerase. The sequence of the ribonucleotide chains was elucidated by end-group labeling with polynucleotide kinase and digestion with various ribonucleases. The ribonucleotide moiety was primarily three and four residues in length with the predominant sequence (pp)pApG(pC)1-2pDNA. The possibility that it represents a primer for discontinuous DNA synthesis is discussed.     

DNA primase-DNA polymerase alpha from simian cells: sequence specificity of initiation sites on simian virus 40 DNA.

Unique single-stranded regions of simian virus 40 DNA, phage M13 virion DNA, and several homopolymers were used as templates for the synthesis of (p)ppRNA-DNA chains by CV-1 cell DNA primase-DNA polymerase alpha. Intact RNA primers, specifically labeled with an RNA capping enzyme, were typically 6 to 8 ribonucleotides long, although their lengths ranged from 1 to 9 bases. The fraction of intact RNA primers 1 to 4 ribonucleotides long was 14 to 73%, depending on the template used. RNA primer length varied among primers initiated at the same nucleotide, as well as with primers initiated at different sites. Thus, the size of an RNA primer depended on template sequence. Initiation sites were identified by mapping 5' ends of nascent RNA-DNA chains on the template sequence, identifying the 5'-terminal ribonucleotide, and partially sequencing one RNA primer. A total of 56 initiation events were identified on simian virus 40 DNA, an average of 1 every 16 bases. Some sites were preferred over others. A consensus sequence for initiation sites consisted of either 3'-dCTTT or 3'-dCCC centered within 7 to 25 pyrimidine-rich residues; the 5' ends of RNA primers were complementary to the dT or dC. High ATP/GTP ratios promoted initiation of RNA primer synthesis at 3'-dCTTT sites, whereas low ATP/GTP ratios promoted initiation at 3'-dCCC sites. Similarly, polydeoxythymidylic acid and polydeoxycytidylic acid were the only effective homopolymer templates. Thus, both template sequence and ribonucleoside triphosphate concentrations determine which initiation sites are used by DNA primase-DNA polymerase alpha. Remarkably, initiation sites selected in vitro were strikingly different from initiation sites selected during simian virus 40 DNA replication in vivo.     

Sequence specificity for the initiation of RNA-primed simian virus 40 DNA synthesis in vivo

Analysis of the nucleotide sequences at the 5' ends of RNA-primed nascent DNA chains (Okazaki fragments) and of their locations in replicating simian virus 40 (SV40) DNA revealed the precise nature of Okazaki fragment initiation sites in vivo. The primary initiation site for mammalian DNA primase was 3'-purine-dT-5' in the DNA template and the secondary site was 3'-purine-dC-5', with the 5' end of the RNA primer complementary to either the dT or dC. The third position of the initiation site was variable with a preference for dT or dA. About 81% of the available 3'-purine-dT-5' sites and 20% of the 3'-purine-dC-5' sites were used. Purine-rich sites, such as PuPuPu and PyPuPu , were excluded. The 5'-terminal ribonucleotide composition of Okazaki fragments corroborated these conclusions. Furthermore, the length of individual RNA primers was not unique, but varied in size from six to ten bases with some appearing as short as three bases and some as long as 12 bases, depending on the initiation site used. This result was consistent with the average size (9 to 11 bases) of RNA primers isolated from specific regions of the genome. Excision of RNA primers did not appear to stop at the RNA-DNA junction, but removed a variable number of deoxyribonucleotides from the 5' end of the nascent DNA chain. Finally, only one-fourth of the replication forks contained an Okazaki fragment, and the distribution of their initiation sites between the two arms revealed that Okazaki fragments were initiated exclusively (99%) on retrograde DNA templates. The data obtained at two genomic sites about 350 and 1780 bases from ori were essentially the same as that reported for the ori region (Hay & DePamphilis , 1982), suggesting that the mechanism used to synthesize the first DNA chain at ori is the same as that used to synthesize Okazaki fragments throughout the genome.     

Evidence that discontinuous DNA replication in Escherichia coli is primed by approximately 10 to 12 residues of RNA starting with a purine

Intact primer RNA for discontinuous DNA replication of Escherichia coli has been detected by specific labeling in vitro of its 5'-terminal tri- (or di-) phosphate group with vaccinia guanylyltransferase and [alpha-32P]GTP. A mutant defective either in RNase H or in both RNase H and DNA polymerase I accumulated about 10 or 30 times more intact primer RNA, respectively, than wild-type cells. The primers started with purine in an A to G ratio of 5 and the most abundant 5'-terminal dinucleotide sequence was (p)ppA-Pu. The chain length of the intact primer RNA was approximately 10 to 12 nucleotide residues. The structural properties of the E. coli primer RNa resemble those of the eukaryotic primer RNA.     

Initiation of SV40 DNA replication in vivo: location and structure of 5' ends of DNA synthesized in the ori region

Initiation sites for DNA synthesis were located at the resolution of single nucleotides in and about the genetically defined origin of replication (ori) in replicating SV40 DNA purified from virus-infected cells. About 50% of the DNA chains contained an oligoribonucleotide of six to nine residues covalently attached to their 5' ends. Although the RNA-DNA linkage varied, the putative RNA primer began predominantly with rA. The data reveal that initiation of DNA synthesis is promoted at a number of DNA sequences that are asymmetrically arranged with respect to ori: 5' ends of nascent DNA are located at several sites within ori, but only on the strand that also serves as the template for early mRNA, while 5' ends of nascent DNA with the opposite orientation are located only outside ori on its early gene side. This clear transition between discontinuous (initiation sites) and continuous (no initiation sites) DNA synthesis defines the origin of bidirectional replication at nucleotides 5210--5211 and demonstrates that discontinuous synthesis occurs predominantly on the retrograde arms of replication forks. Furthermore, it appears that the first nascent DNA chain is initiated within ori by the same mechanism used to initiate nascent DNA ("Okazaki fragments") throughout the genome.     

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.     

Nascent DNA chains synthesized in reversibly permeable cells of mouse thymocytes

Freshly prepared thymocytes continue to synthesize DNA under hypotonic conditions in the presence of 4.5% dextran T-150, the four deoxyribonucleoside triphosphates and ATP. Permeable cells could seal the membrane in a serum-enriched medium within a few hours. 2'-Deoxycytidine 5'-triphosphate is effectively substituted by 5-mercuri-2'-deoxycytidine 5'-triphosphate as a substrate. The newly synthesized mercurated DNA can be separated from cellular DNA and RNA on a thiol-agarose affinity matrix. The rate of incorporation of [3H]thymidine triphosphate into permeable cells is the same as that of the incorporation of [3H]thymidine into intact cells, corresponding to approximately 30% of the rate in vivo. Synthesis in permeable cells reflects DNA replication shown by inhibitors such as 1-beta-D-arabinofuranosylcytosine 5'-triphosphate (aCTP), nalidixic acid and novobiocin and by density shift experiments. More than 80% of the newly synthesized low-molecular-mass DNA, 8-60 nucleotides in length, consists of RNA-linked DNA. This conclusion is based on phosphorylation with [gamma-32]ATP and polynucleotide kinase and rephosphorylation after alkaline hydrolysis. The 5' end of RNA consists of adenylate, guanylate, cytidylate and uridylate residues in a ratio of 4:3:1.5:1.5.     

An Okazaki piece of simian virus 40 may be synthesized by ligation of shorter precursor chains.

It is generally accepted that an aphidicolin-sensitive DNA polymerase elongates the eucaryotic RNA primer (iRNA) into a mature Okazaki piece reaching ca. 200 nucleotides. Yet, as shown here, nascent DNA chains below 40 nucleotides accumulated in simian virus 40 (SV40) DNA replicating in isolated nuclei in the presence of aphidicolin. These products resembled precursors of longer Okazaki pieces synthesized in the absence of aphidicolin (termed here DNA primers) in size distribution, lagging-replication-fork polarity, and content of iRNA. Within the isolated SV40 replicative intermediate, DNA primers could be extended in a reaction catalyzed by the Escherichia coli DNA polymerase I large fragment. This increased their length by an average of 21 deoxyribonucleotide residues, indicating that single-stranded gaps of corresponding length existed 3' to the DNA primers. Incubation with T4 DNA ligase converted most of the extended DNA primers into products resembling long Okazaki pieces. These data led us to propose that the synthesis of an SV40 Okazaki piece could be itself discontinuous and could comprise the following steps: (i) iRNA synthesis by DNA primase, (ii) iRNA extension into a DNA primer by an aphidicolin-resistant activity associated with DNA primase-DNA polymerase alpha, (iii) removal of iRNA moieties between adjacent DNA primers, (iv) "gap filling" between DNA primers by the aphidicolin-sensitive DNA polymerase alpha, and (v) ligation of DNA primer units onto a growing Okazaki piece. Eventually, a mature Okazaki piece is ligated onto a longer nascent DNA chain.     

Selective isolation of mercurated DNA by affinity chromatography on thiol matrices

A method for isolating picomole quantities of nascent mercurated DNA from a mixture of cellular nucleic acids using affinity chromatography on thiol-agarose is described. Analysis of mercurated DNA (HgDNA) isolated in the presence of in vivo-labeled cellular RNA or in vitro-synthesized RNA showed a low level of RNA contamination, about 0.04-0.16%, in the HgDNA. Comparative binding studies on different thiol matrices showed that the efficiency of binding of HgDNA was related to the nature but not to the SH content of the matrix used. Another important parameter for binding was the structure of HgDNA. The recovery was 98% with large nascent HgDNA sedimenting at about 30 S, whereas for short pulse-labeled single-stranded HgDNA (20-50 nucleotides long), the maximum recovery was 60%. The effect of the structure of HgDNA on the binding to the thiol matrix was probed using a variety of well-defined mercurated structures obtained from phage DNA and their restriction fragments. For DNA containing one 5-mercuricytidine 5'-triphosphate (HgdCMP) residue at each 3'-end, short fragments (size range, 230-510 bp) were bound quantitatively. With larger fragments (size range, 490-1100 bp), the binding decreased progressively with increasing size. DNA fragments larger than 1060 bp did not bind to the matrix. Single-stranded DNA containing only one HgdCMP at one end did not bind to the matrix even in the size range 200-1100 nucleotides. In contrast, continuous stretches of HgdCMP residues in one strand or short stretches of HgdCMP residues at random in both strands permit quantitative binding irrespective of size.     

Alkali-labile structures linked to the 5'' ends of Bacillus subtilis short DNA chains.

Alkali-labile portion covalently linked to the 5' ends of Bacillus subtilis short DNA chains, the putative primer RNA for discontinuous DNA synthesis, was isolated and analyzed using a temperature sensitive DNA polymerase I mutant, which accumulates nascent DNA fragments at a restrictive temperature. A novel oligonucleotide structure as well as mono- to triribonucleotide stretches were isolated at the 5' end of the short DNA chains. A structure for the novel oligonucleotide is proposed to be p5' X3' pp5' rN, where X represents unidentified nucleoside with a peculiar property. Possible metabolic relationship between these molecules and primer RNA has been discussed.     

Precise mapping and characterization of the RNA primers of DNA replication for a yeast hypersuppressive petite by in vitro capping with guanylyltransferase.

The active origins of DNA replication for yeast (Saccharomyces cerevisiae) mitochondrial DNA share 280 conserved base pairs and have a promoter. Since intact replication intermediates retain their initiating ribonucleotide triphosphate, we used guanylyltransferase to in vitro cap the replication intermediates present in restriction enzyme-cut DNA from an ori-5 hypersuppressive petite. Restriction mapping and RNA sequencing of these labeled intermediates showed that each DNA strand is primed at a single discrete nucleotide, that one primer starts at the promoter and that the other primer starts 34 nt away, outside the conserved region. Deoxyribonuclease digestion of the capped fragments left resistant RNA primers, which enabled identification of zones of transition from RNA to DNA synthesis. Some of the results contradict the prevailing model for priming at the yeast mitochondrial origins.     

Discontinuous DNA replication of Drosophila melanogaster is primed by octaribonucleotide primer.

To investigate the precise structure of eucaryotic primer RNA made in vivo, short DNA chains isolated from nuclei of Drosophila melanogaster embryos were analyzed. Post-labeling of 5' ends of short DNA chains with polynucleotide kinase and [gamma-32P]ATP revealed that 7% of the DNA fragments were covalently linked with mono- to octaribonucleotide primers at their 5' ends. Octaribonucleotides, the major component (ca. 30%), formed the cap structure in the reaction with vaccinia guanylyltransferase and [alpha-32P]GTP, indicating that they were the intact primer RNA with tri- (or di-) phosphate termini, and the shorter ribooligomers were degradation intermediates. The intact primers started with purine (A/G ratio, 4:1), and the starting few ribonucleotide residues were rich in A.     

The role of RNA primer in discontinuous DNA replication in isolated nuclei from HeLa cells

RNA-primed discontinuous DNA synthesis was studied in an in vitro system consisting of washed nuclei from synchronized S-phase HeLa cells. A new technique proved useful for the purification of short nascent fragments of DNA (Okazaki fragments). Mercurated dCTP was substituted for dCTP in the DNA synthesis reaction. Short nascent pieces (4–6 S) of mercurated DNA were found to bind preferentially to sulfhydryl-agarose, and could be eluted with mercaptoethanol. The isolated fragments were assayed for the presence of covalently linked RNA by the spleen exonuclease method described by Kurosawa et al. (Kurosawa, Y., Ogawa, T., Hirose, S., Okazaki, T. and Okazaki, R. (1975) J. Mol. Biol. 96, 653–664). Following a 30 s incubation with [³H]TTP in the absence of added ribonucleotides, approximately 20% of the nascent strands synthesized in washed nuclear preparations had RNA attached. These RNA primers either preexisted in the nuclei or were formed from endogenous ribonucleotides. The 5′ ends of the primers appeared to be largely in a phosphorylated state. In the absence of added ribonucleotides, these RNA-DNA linkages disappeared within 2 min, whereas if ribonucleotides were added, the number of RNA primers increased to 40% and remained at this level for greater than 2 min. To obtain maximal levels of RNA primer, the addition of all three of the ribonucleotides, rCTP, rGTP and rUTP (0.1 mM), as well as high levels of rATP (5 mM) was required. Addition of ribonucleotides also markedly enhanced the amount of nascent DNA fragments synthesized. However, in the absence of added ribonucleotides, after RNA primers had disappeared, nascent DNA fragments were still initiated at a significant rate. These results suggest that RNA primers play an important role in the initiation of Okazaki fragments but that synthesis can also be initiated by alternative mechanisms. An important role for ATP in RNA primer synthesis is suggested.     

Guanosine triphosphate promotes the post-translational integration of opsin into the endoplasmic reticulum membrane

Membrane integration of a nascent opsin polypeptide was examined to determine whether insertion of proteins into the endoplasmic reticulum is dependent upon energy provided by ribonucleotide triphosphate hydrolysis. A discrete-sized nascent chain was obtained by in vitro translation of a mRNA which lacked a termination codon yet encoded the first 156 residues of bovine opsin. Ribosomes bearing the newly synthesized opsin chains were post-translationally incubated with canine pancreas microsomal membrane vesicles after addition of exogenous ribonucleotides or ribonucleotide analogues. Post-translational membrane integration and glycosylation of the 156-residue nascent polypeptide was found to require either the presence of guanosine triphosphate or a nonhydrolyzable GTP analogue. ATP did not promote post-translational integration of the nascent polypeptide. Although ribonucleotide hydrolysis was not obligatorily required for integration of opsin, we observed an increase in the proportion of glycosylated opsin chains in post-translational incubations that contained hydrolyzable ribonucleotide triphosphates. We conclude that a GTP-binding protein performs an essential role during integration of opsin into the endoplasmic reticulum.     

T7 gene 6 exonuclease has an RNase H activity.

T7 gene 6 exonuclease has been shown to have an RNase H activity as well as a double-strand specific DNase activity by the following experiments: The RNase H activity coelutes with the DNase activity from DEAE-cellulose, phosphocellulose, hydroxyapatite, and Sephadex G-200 columns. Gene 6 exonuclease specified by a T7 strain with a temperature sensitive mutation in gene 6 has an extremely heat-labile RNase H activity as well as a heat-labile DNase activity. T7 gene 6 exonuclease degrades the RNA region of a poly(A) . poly(dT) hybrid polymer exonucleolytically from the 5' terminus, releasing a ribonucleoside 5'-monophosphate product. When the RNA strand of a 0X174 RNA . DNA hybrid molecule synthesized with E. coli RNA polymerase is degraded, a ribonucleoside triphosphate is produced from the 5'-triphosphate terminus. Participation of T7 gene 6 exonuclease in the removal of primer RNA in discontinuous replication of T7 DNA is discussed.     

Reduction of the potent DNA polymerase III holoenzyme 3'----5' exonuclease activity by template-primer analogues

The DNA polymerase III holoenzyme of Escherichia coli contains a potent 3'----5' exonuclease that removes the terminal nucleotide from a synthetic deoxyoligonucleotide primer with a half-life of approximately 2 s. Degradation of primers could not be effectively prevented by permitting the holoenzyme to "idle" at the primer terminus in the presence of limited deoxynucleoside triphosphates. To further characterize this exonuclease and to develop stable primers to facilitate experimental manipulations, we synthesized a series of twelve 25-mer oligonucleotides that differed only in the two 3'-terminal residues. The penultimate position contained either a CMP or a dCMP residue, while at the terminal position either AMP, dAMP, 2',3'-dideoxyAMP, cordycepin (3'-dAMP), dAMP alpha S, or 2',3'-dideoxyAMP alpha S was incorporated. No single change at either the 3'-penultimate or 3'-terminal positions resulted in a decrease in the exonuclease rate greater than 10-fold; however, combined changes at these two sites resulted in a strong synergistic effect. Placing a ribonucleotide at the penultimate position coupled by a phosphorothioate linkage to a terminal 2',3'-dideoxynucleotide reduced the rate of exonucleolytic activity almost 30,000-fold (half-life approximately 16 h). If only the ribonucleotide and phosphorothioate substitutions were made, a primer capable of being efficiently elongated was generated that exhibited a 500-fold increase in stability (half-life = 40 min). The elemental effect observed by substituting a nonbridging oxygen in the terminal phosphodiester bond for sulfur increased from 1.5 to 200 as other substitutions were made that decreased the exonuclease rate. This was consistent with a change in the rate-limiting step of the exonuclease reaction from a conformational change to the chemical step where the covalent bond is cleaved. At least part of this effect appears to be due to perturbations within the enzyme's active site and not solely due to changes in electrophilicity.     

Discontinuous synthesis of both strands at the growing fork during polyoma DNA replication in vitro.

In discontinuous polyoma DNA replication, the synthesis of Okazaki fragments is primed by RNA. During viral DNA synthesis in nuclei isolated from infected cells, 40% of the nascent short DNA fragments had the polarity of the leading strand which, in theory, could have been synthesized by a continuous mechanism. To rule out that the leading strand fragments were generated by degradation of nascent DNA, they were further characterized. DNA fragments from a segment of the genome which replication forks pass in only one direction were strand separated. The sizes of the fragments from both strands were similar, suggesting that one strand was not specifically degraded. Most important, however, the majority of the Okazaki fragments of both strands were linked to RNA at their 5' ends. For identification, the RNA was labeled at the 5' ends by [beta-32P]GTP, internally by [3H]CTP, [3H]GTP, and [3H]UTP, or at the 3' ends by 32P transfer from adjacent [32P]dTMP residues. All three kinds of labeling indicated that an equal proportion of DNA fragments from the two strands was linked to RNA primers.