Replication termini in the rDNA of synchronized pea root cells (Pisum sativum)

In synchronized root cells of Pisum sativum (cv. Alaska) the joining of nascent replicons is delayed until cells reach the S-G(2) boundary or early G(2) phase. To determine if the delayed ligation of nascent chains occurs at specific termination sites, we mapped the location of arrested forks in the ribosomal DNA (rDNA) repeats from cells in late S and G(2) phases. Two-dimensional (neutral-alkaline) agarose electrophoresis and Southern blot hybridization with specific rDNA sequences show that only cells located at the S-G(2) boundary and early G(2) phase produce alkali-released rDNA fragments of discrete size. The released fragments are from a particular restriction fragment, demonstrating that the replication forks stop non-randomly within the rDNA repeats. Indirect end-labeling with probes homologous to one or the other end of the fork-containing restriction fragment shows that there are two termination regions, T(1) and T(2), where forks stop. T(1) is located in the non-transcribed spacer and T(2) is at the junction between the non-transcribed spacer and the 18S gene. The two termini are separated by 1.3 kb. Replication forks stop at identical sites in both the 8.6- and 9.0-kb rDNA repeat size classes indicating that these sites are sequence determined.     

In vitro polyoma DNA synthesis: discontinuous chain growth

Using an in vitro system for polyoma DNA synthesis from polyoma-infected mouse BALB/3T3 cells, we have shown that short pulses of radioactively labeled deoxynucleoside triphosphates are incorporated into viral replicative intermediates. Upon denaturation, the pulse-labeled replicative intermediates yield two size classes of growing DNA chains, namely a heterogeneous long class with S values up to unit viral DNA length (16 S) and a rather discrete short class of 5 S pieces. We have shown that these short fragments are involved as precursors in viral DNA chain elongation and that they can be chased into mature viral DNA. The fragments are found in replicative intermediates at all stages of replication and are therefore presumably not involved in specialized initiation or termination processes. Kinetic analysis of the appearance of radioactivity in short and long chains shows that initially approximately equal amounts are incorporated at a linear rate into the two classes. Subsequently, the rate of incorporation into long chains approximately doubles, while the amount of radioactivity in short chains reaches a plateau. This not only suggests that short chains are precursors to long chains, but that the synthesis of long chains occurs as a separate event and is not simply a result of joining of short fragments. Under the in vitro labeling conditions the time taken for radioactivity in short chains to reach a constant level can be used as a measure of the average lifetime of a 5 S piece. Our analysis indicates that there may be a considerable lag between the completion of a 5 S piece and its joining into longer DNA. Estimates of the self-annealing of the short chains showed approximately 20% self-complementarity. Thus, polyoma synthesis in vitro appears to proceed predominantly by a semi-discontinuous mechanism in which the nascent DNA on one side of the growing fork is elongated continuously, while on the other side of the fork DNA is synthesized discontinuously as 5 S fragments, which are subsequently joined. Both the short and the long chains are synthesized in the 5′ to 3′ direction.A fraction of the pulse-labeled material is found as free 3 to 5 S single-stranded DNA. These pieces are of both viral and cellular origin. A majority of them appear to be involved as precursors in DNA chain elongation.     

Replication Process of the Parvovirus H-1 III. Factors Affecting H-1 RF DNA Synthesis

Replication of the single-stranded DNA parvovirus H-1 involves the synthesis of a double-stranded DNA replicative form (RF). In this study, the metabolism of RF DNA was examined in parasynchronous hamster embryo cells. The initiation of RF DNA replication was found to occur late in S phase, as was the synthesis of the DNA upon which subsequent viral hemagglutinin synthesis is dependent. Evidence is presented which indicates that initiation of RF replication requires proteins synthesized in late S phase, but that concomittant protein synthesis is not required for the continuation of RF replication. The data also suggest a requirement for viral protein(s) for progeny strand synthesis. Incorporation of 5-bromo-2'-deoxyuridine (BUdR) into viral DNA resulted in an "all-or-none" inhibition of viral hemagglutinin and viral antigen synthesis. BUdR inactivation of viral protein function was used to explore the time of synthesis of viral DNA serving as template for viral RNA synthesis and the effect of viral protein on RF replication and progeny strand synthesis. Results of this study suggest that parental RF DNA is synthesized shortly after infection, and that viral mRNA is transcribed from only a few copies of the viral genome in each cell. They also support the conclusion that viral protein is inhibitory to RF DNA replication. Density labeling of RF DNA with BUdR, allowing separation of viral strand DNA (V) from viral complementary strand (C), provided additional data in support of the above findings.     

Excision and replication of extrachromosomal DNA of pea (Pisum sativum).

Experiments with cultured pea roots were conducted to determine (i) whether extrachromosomal DNA was produced by cells in the late S phase or in the G2 phase of the cell cycle, (ii) whether the maturation of nascent DNA replicated by these cells achieved chromosomal size, (iii) when extrachromosomal DNA was removed from the chromosomal duplex, and (iv) the replication of nascent chains by the extrachromosomal DNA after its release from the chromosomal duplex. Autoradiography and cytophotometry of cells of carbohydrate-starved root tips revealed that extrachromosomal DNA was produced by a small fraction of cells accumulated in the late S phase after they had replicated about 80% of their DNA. Velocity sedimentation of nascent chromosomal DNA in alkaline sucrose gradients indicated that the DNA of cells in the late S phase failed to achieve chromosomal size. After reaching sizes of 70 X 10(6) to 140 X 10(6) daltons, some of the nascent chromosomal molecules were broken, presumably releasing extrachromosomal DNA several hours later. Sedimentation of selectively extracted extrachromosomal DNA either from dividing cells or from those in the late S phase showed that it replicated two nascent chains, one of 3 X 10(6) daltons and another of 7 X 10(6) daltons. Larger molecules of extrachromosomal DNA were detectable after cells were labeled for 24 h. These two observations were compatible with the idea that the extrachromosomal DNA was first replicated as an integral part of the chromosomal duplex, was cut from the duplex, and then, once free of the chromosome, replicated two smaller chains of 3 X 10(6) and 7 X 10(6) daltons.     

Adenovirus deoxyribonucleic acid replication. II. Synthesis of viral deoxyribonucleic acid in vitro by a nuclear membrane fraction from infected KB cells.

A cell-free system for the study of viral DNA replications was developed by the isolation of a nuclear membrane fraction "DNA replication complex" from adenovirus 2-infected human KB cells late after infection. This complex which possesses both DNA polymerase activity and a virus-specific endonuclease synthesizes exclusively virus-specific DNA sequences in vitro by a semiconservative mechanism. Analysis by rate zonal sedimentation in alkaline sucrose gradients showed that the products of the reaction are small DNA chains approximately 6 to 9 S, presumably "Okazaki intermediates," that are not sealed under our in vitro conditions. Analysis by rate zonal sedimentation in neutral sucrose gradients showed that labeled viral DNA fragments are hydrogen bonded to viral 18 S DNA segments, 0.25 the size of the linear, viral 31 S DNA genome. The 18 S DNA is probably a specific cleavage product of the viral endonuclease found in the replication complex and could represent intermediates in viral DNA replication or degradation products.     

An analysis of DNA replication in synchronized CHO cells treated with benzo[a]pyrene diol epoxide

Synchronized Chinese hamster ovary (CHO) cells treated with (+/-)7 beta,8 alpha- dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10-dihydrobenzo[a]pyrene (BP diol epoxide I) were used to test the 'block-gap' model of replicative bypass repair in mammalian cells. One feature of the model is that carcinogenic or mutagenic DNA adducts act as blocks to the DNA replication fork on the leading strand. Using synchronized CHO cells, the rate of S phase progression by BrdUrd labeling of newly replicated DNA was measured. The rate of S phase progression was reduced by 22% and 42%, when the cells were treated at the G1/S boundary with 0.33 and 0.66 microM BP diol epoxide I, respectively. Using the pH step alkaline elution assay, it was found that the reduced rate of S phase progression was due to a delay in the appearance of multiple replicon size nascent DNA. This observation was consistent with the frequency of BP-DNA adducts present in the leading strand. A second feature of the 'block-gap' model is that the adduct-induced blockage on the lagging strand will produce gaps. It was determined by the use of high-resolution agarose gel electrophoresis, that the ligation of Okazaki size replication intermediates was blocked in a dose-dependent manner in BP diol epoxide I treated, synchronized CHO cells. These data are consistent with a block to the leading strand of DNA replication at DNA-carcinogen adducts. An inhibition of the ligation of Okazaki size fragments by BP diol epoxide I implies a block to replication of the DNA lagging strand leading to gap formation. The data presented here are, therefore, supportive of the 'block-gap' model of replicative bypass repair in carcinogen damaged mammalian cells.     

Coordinated leading- and lagging-strand synthesis at the Escherichia coli DNA replication fork. V. Primase action regulates the cycle of Okazaki fragment synthesis.

Replication forks formed during rolling-circle DNA synthesis supported by a tailed form II DNA substrate in the presence of the primosome, the single-stranded DNA binding protein, and the DNA polymerase III holoenzyme (Pol III HE) that had been reconstituted from the purified subunits, beta, tau, and the gamma.delta complex, at limiting (with respect to nucleotide incorporation) concentrations of the Pol III core (alpha, epsilon, and theta) produced aberrantly small Okazaki fragments, while the synthesis of the leading strand was unperturbed. These small Okazaki fragments were not arrayed in tandem along the lagging-strand DNA template, but were separated by large gaps. Similarly structured synthetic products were not manufactured by replication forks reconstituted with higher, saturating concentrations of the Pol III core. Replication forks producing these small fragments could respond, by modulating the size of the Okazaki fragments produced, to variations in the concentration of NTPs or the primase, conditions that affect the frequency of priming on the lagging strand, but not to variation in the concentration of dNTPs, conditions that affect the frequency of utilization of the primers. Significantly longer Okazaki fragments (greater than 7 kilobases) could be produced in the presence of a limiting amount of Pol III core at low concentrations of the primase. These observations indicated that the production of small Okazaki fragments was not a result of a debilitated lagging-strand Pol III core, but rather a function of the time available for nascent strand synthesis during the cycle of events that are required for the manufacture of an Okazaki fragment and that it was the association of primase with the replication fork that keyed this cycle.     

Properties of a membrane-attached form of the folded chromosome of Escherichia coli

Two types of DNA-containing particles are released from lysozyme-produced Escherichia coli spheroplasts after gentle lysis with non-ionic detergents in 1.-0 m-NaCl. Lysis at 25 °C releases the folded chromosomes (1300 S to 2200 S particles). Lysis at 10 °C results in faster sedimenting structures (3000 S to 4000 S). Both types of particles coexist in extracts of cells lysed at intermediate temperatures, i.e. 15 °C.The 3000 S to 4000 S particles are folded chromosomes attached to membrane fragments; they contain membrane proteins and phospholipids in addition to the folded DNA and nascent RNA chains. Incubation of the membrane-attached chromosomes with 1% Sarkosyl releases the folded chromosomes; this Sarkosyl treatment removes the membrane proteins and phospholipids, and halves the sedimentation velocity of the particles, but has no effect on the folded DNA and nascent RNA chains.Membrane-attached chromosomes cannot be isolated from amino acid-starved cells which have completed their rounds of DNA replication; all of the DNA then appears as released folded chromosomes. After resumption of protein synthesis, chromosome attachment to the membrane precedes the initiation of DNA replication. Controls strongly suggest that the changes observed, i.e. the attachment and release from the membrane of the folded chromosome, are related to the act of DNA replication itself.     

Mode of extension of the daughter strands in the replication of closed circular mitochondrial DNA in vitro.

1. The properties of nascent DNA in the replicative closed circular mitochondrial DNA were examined in the in vitro system of discontinuous replication, using newborn rat liver mitochondria containing endogeneous DNA templates and enzymes. 2. The nascent DNA associated with the closed circular DNA fraction was found to be of two types; one class consisted of the fragments, and the other of the higher molecular-weight DNAs. Data from pulse and chase experiments indicate that the fragments were initially synthesized and subsequently converted into both heavy and light strands of the higher molecular-weight DNAs in an asymmetrical mode. 3. DNA - DNA hybridization experiments revealed that half of the fragments at least were copies of complementary parts of the parental DNA. 4. Based on the present in vitro data, a tentative structure of the replicating region and its expansion are discussed.     

Switching from high-fidelity replicases to low-fidelity lesion-bypass polymerases

Replication of damaged DNA often requires a DNA polymerase in addition to the cell's normal replicase. Recent research has begun to shed light on the switch from a high-fidelity replicative polymerase to a low-fidelity translesion polymerase that occurs at a stalled replication fork. A picture is emerging in which eukaryotic replicative clamps are posttranslationally modified by ubiquitination, SUMOylation or phosphorylation. It is believed that such modifications help to regulate the access of translesion polymerases to the nascent primer terminus.     

Intermediate in adenovirus type 2 replication.

Replicating chromosomes, called intermediate DNA, have been extracted from the adenovirus replication complex. Compared to mature molecules, intermediate DNA had a greater buoyant density in CsCl gradients and ethidium bromide-cesium chloride gradients. Digestion of intermediate DNA with S1 endonuclease, but not with RNase, abolished the difference in densities. These properties suggest that replicating molecules contain extensive regions of parental single strands. Although intermediate DNA sedimented faster than marker viral DNA in neutral sucrose gradients, single strands longer than unit length could not be detected after alkaline denaturation. Integral size classes of nascent chains in intermediate DNA suggest a relationship between units of replication and the nucleoprotein structure of the virus chromosome. Adenovirus DNA was replicated at a rate of 0.7 x 10-6 daltons/min. Although newly synthesized molecules had the same sedimentation coefficient and buoyant density as mature chromosomes, they still contained single-strand interruptions. Complete joining of daughter strands required an additional 15 to 20 min.     

Replication Process of the Parvovirus H-1 II. Isolation and Characterization of H-1 Replicative Form DNA

The Parvovirus H-1 replicates autonomously in hamster embryo cells. A DNA synthetic event, called HA-DNA synthesis, upon which subsequent viral RNA and viral hemagglutinin synthesis is dependent, is initiated in late S phase of the infected cell (18). It was postulated that HA-DNA represents parental viral replicative form DNA (RF DNA). This study describes the isolation and characterization of H-1 RF DNA as part of the continuing study of the mechanisms and control of DNA replication in the eukaryotic cell. The H-1 RF DNA is a linear duplex molecule containing the viral strand and its complement. The complementary strands of the RF DNA have been separated by equilibrium density gradient centrifugation. The RF DNA has a buoyant density of 1.705 in neutral CsCl and an estimated guanine plus cytosine (GC) content of 45.9%. It has a sedimentation coefficient of 17S. The calculated molecular weight of 3.7 x 10(6) is twice that of the single-stranded virion DNA. H-1 virions contain DNA that is homogeneous and free of complementary strands.     

Bacteriophage G4 DNA synthesis in temperature-sensitive dna mutants of Escherichia coli.

The synthesis of bacteriophage G4 DNA was examined in temperature-sensitive dna mutants under permissive and nonpermissive conditions. The infecting single-stranded G4 DNA was converted to the parental replicative form (RF) at the nonpermissive temperature in infected cells containing a temperature sensitive mutation in the dnaA, dnaB, dnaC, dnaE, or dnaG gene. The presence of 30 mug of chloramphenicol or 200 mug of rifampin per ml had no effect on parental RF synthesis in these mutants. Replication of G4 double-stranded RF DNA occurred at a normal rate in dnaAts cells at the nonpermissive temperature, but the rate was greatly reduced in cells containing a temperature-sensitive mutation in the dnaB, dnaC, dnaE, or dnaG gene. RF DNA replicated at normal rates in revertants of these dna temperature-sensitive host cells. The simplest interpretation of these observations is that none of the dna gene products tested is essential for the synthesis of the complementary DNA strand on the infecting single-stranded G4 DNA, whereas the dnaB, dnaC, dnaE, (DNA polymerase III), and dnaG gene products are all essential for replication of the double-stranded G4 RF DNA. The alternate possibility that one or more of the gene products are actually essential for G4 parental RF synthesis, even though this synthesis is not defective in the mutant hosts, is also discussed.     

Site-specific initiation of DNA replication in Xenopus egg extract requires nuclear structure.

Previous studies have shown that Xenopus egg extract can initiate DNA replication in purified DNA molecules once the DNA is organized into a pseudonucleus. DNA replication under these conditions is independent of DNA sequence and begins at many sites distributed randomly throughout the molecules. In contrast, DNA replication in the chromosomes of cultured animal cells initiates at specific, heritable sites. Here we show that Xenopus egg extract can initiate DNA replication at specific sites in mammalian chromosomes, but only when the DNA is presented in the form of an intact nucleus. Initiation of DNA synthesis in nuclei isolated from G1-phase Chinese hamster ovary cells was distinguished from continuation of DNA synthesis at preformed replication forks in S-phase nuclei by a delay that preceded DNA synthesis, a dependence on soluble Xenopus egg factors, sensitivity to a protein kinase inhibitor, and complete labeling of nascent DNA chains. Initiation sites for DNA replication were mapped downstream of the amplified dihydrofolate reductase gene region by hybridizing newly replicated DNA to unique probes and by hybridizing Okazaki fragments to the two individual strands of unique probes. When G1-phase nuclei were prepared by methods that preserved the integrity of the nuclear membrane, Xenopus egg extract initiated replication specifically at or near the origin of bidirectional replication utilized by hamster cells (dihydrofolate reductase ori-beta). However, when nuclei were prepared by methods that altered nuclear morphology and damaged the nuclear membrane, preference for initiation at ori-beta was significantly reduced or eliminated. Furthermore, site-specific initiation was not observed with bare DNA substrates, and Xenopus eggs or egg extracts replicated prokaryotic DNA or hamster DNA that did not contain a replication origin as efficiently as hamster DNA containing ori-beta. We conclude that initiation sites for DNA replication in mammalian cells are established prior to S phase by some component of nuclear structure and that these sites can be activated by soluble factors in Xenopus eggs.     

Initiation of simian virus 40 DNA replication in vitro: identification of RNA-primed nascent DNA chains.

Cell-free extracts of simian virus 40 (SV40)-infected CV-1 cells can initiate large tumor antigen dependent bidirectional replication in circular DNA molecules containing a functional SV40 origin of replication (ori). To determine whether or not DNA replication under these conditions involves RNA-primed DNA synthesis, replication was carried out in the presence of 5-mercuri-deoxycytidine triphosphate to label nascent DNA chains. Newly synthesized mercurated DNA was isolated by its affinity for thiol-agarose, and the 5'-ends of the isolated chains were radiolabeled to allow identification of RNA primers. At least 50% of the isolated chains contained 4 to 7 ribonucleotides covalently linked to their 5'-end; 80% of the oligoribonucleotides began with adenosine and 19% began with guanosine. About 60% of the nascent DNA chains annealed to the SV40 ori region, and about 80% of these chains were synthesized in the same direction as early mRNA. These results are consistent with the properties of SV40 DNA replication in vivo and support a model for initiation of SV40 DNA replication in which DNA primase initiates DNA synthesis on that strand of ori that encodes early mRNA.     

rDNA enhancer affects replication initiation and mitotic recombination: Fob1 mediates nucleolytic processing independently of replication

To investigate the influence of the ribosomal DNA enhancer on initiation of replication and recombination at the ribosomal array, we used yeast S. cerevisiae strains with adjacent, tagged rRNA genes. We found that the enhancer is an absolute requirement for replication fork barrier function, while it only modulates initiation of replication. Moreover, the formation of monomeric extrachromosomal ribosomal circles depends on this element. Our data indicate that DNA double-strand breaks occur at specific sites in the parental leading arm of replication forks stalled at the replication fork barrier. Additionally, nicks upstream of the replication fork barrier were visualized by nucleotide-resolution mapping. They coincide with essential sequences of the mitotic hyperrecombination site HOT1, which previously has been determined at ectopic sites. Interestingly, these nicks are strictly dependent on the replication fork blocking-protein (Fob1), but are replication independent, suggesting that intrachromosomal ribosomal DNA recombination may occur outside of S phase.     

Metabolism of Okazaki fragments during simian virus 40 DNA replication.

Essentially all of the Okazaki fragments on replicating Simian virus 40 (SV40)DNA could be grouped into one of three classes. Class I Okazaki fragments (about 20%) were separated from longer nascent DNA chains by a single phosphodiester bond interruption (nick) and were quantitatively identified by treating purified replicating DNA with Escherichia coli DNA ligase and then measuring the fraction of Okazaki fragments joined to longer nascent DNA chains. Similarly, class II Okazaki fragments (about 30%) were separated by a region of single-stranded DNA template (gap) that could be filled and sealed by T4 DNA polymerase plus E. coli DNA ligase, and class III fragments (about 50%) were separated by RNA primers that could be removed with E. coli DNA olymerase I, allowing the fragments to be joined with E. coli DNA ligase. These results were obtained with replicating SV40 DNA that had been briefly labeled with radioactive precursors in either intact cells or isolated nuclei. When isolated nuclei were further incubated in the presence of cytosol, all of the Okazaki fragments were converted into longer DNA strands as expected for intermediates in DNA synthesis. However, when washed nuclei were incubated in the abscence of cytosol, both class I and class II Okazaki fragments accumulated despite the excision of RNA primers: class III Okazaki fragments and RNA-DNA covalent linkages both disappeared at similar rates. These data demonstrate the existence of RNA primers in whole cells as well as in isolated nuclei, and identify a unique gap-filling step that is not simply an extension of the DNA chain elongation process concomitant with the excision of RNA primers. One or more factos found in cytosol, in addition to DNA polymerase alpha, are specifically involved in the gap-filling and ligation steps. The sizes of mature Okazaki fragments (class I) and Okazaki fragments whose synthesis was completed by T4 DNA polymerase were measured by gel electrophoresis and found to be broadly distributed between 40 and 290 nucleotides with an average length of 135 nucleotides. Since 80% and 90% of the Okazaments does not occur at uniformly spaced intervals along the DNA template. During the excision of RNA primers, nascent DNA chains with a single ribonucleotide covalently attached to the 5' terminus were identified as transient intermediates. These intermediates accumulated during excision of RNA primers in the presence of adenine 9-beta-D-arabinoside 5'-triphosphate, and those Okazaki fragments blocked by RNA primers (class III) were found to have originated the farthest from the 5' ends of long nascent DNA strands. Thus, RNA primers appear to be excised in two steps with the second step, removal of the final ribonucleotide, being stimulated by concomitant DNA synthesis. These and other data were used to construct a comprehensive metabolic pathway for the initiation, elongation, and maturation of Okazaki fragments at mammalian DNA replication forks.     

Multiplication of parvovirus LuIII in a synchronized culture system. III. Replication of viral DNA.

The replication of the single-stranded DNA (ssDNA) of parvovirus LuIII was studied in synchronized HeLa cells. After infection of the cells in early S phase, synthesis of a replicative form (RF) DNA became detectable as early as 9 h postinfection, i.e., after display of the cellular helper function(s) indispensable for the replication of LuIII virus. According to digestion with nuclease S1, hybridization studies, and electron microscopy, RF DNA is a linear, double-stranded molecule comparable in length to mature ssDNA. It sedimented around 15S in neutral solution and banded at 1.714 g/ml in CsCl. Moreover, replication of LuIII DNA obviously includes a further replicative intermediate DNA which sedimented in front of RF DNA and bore single-stranded side-chains. Newly synthesized DNA disappeared from pools containing both RF DNA and replicative intermediate DNA within 5 min and reappeared in progeny virions only after 15 min. Intranuclear accumulation of significant amounts of progeny ssDNA could not be detected. It was postulated, therefore, that newly synthesized ssDNA is immediately enclosed in a stable maturation complex and resists extraction by the method of Hirt (1967).