Complete enzymatic replication of plasmids containing the origin of the Escherichia coli chromosome

During enzymatic replication of plasmids containing the origin of the Escherichia coli chromosome, oriC, formation of an active initiation complex consisting of dnaA, dnaB, dnaC, and HU proteins, requires a supercoiled DNA template. Relaxed covalently closed plasmids are active only if supercoiled by gyrase prior to initiation; nicked and linear DNAs are inactive. Semi-conservative replication proceeds via delta structure as intermediates. Daughter molecules include nicked intermediates. Daughter molecules include nicked monomers and catenated pairs. Elongation is rapid, but late replicative intermediates accumulate because the final elongation and termination steps are slow. Production of covalently closed circular daughter DNA molecules requires removal of ribonucleotide residues (primers) by DNA polymerase I, assisted by ribonuclease H, gap filling, and ligation of nascent strands by ligase. Reconstitution of a complete cycle of oriC plasmid replication, beginning and ending with supercoiled molecules, has been achieved with purified proteins.     

E. coli minichromosome replication in vitro and in vivo: comparative analyses of replication intermediates

The process of replication of Escherichia coli minichromosomes was examined by following the intermediates formed in vitro and in vivo. Replication initiated on a supercoiled closed circular (CC) monomer, proceeded rapidly to a late but incomplete stage in polymerization (the LC form) in both systems, passed more slowly through a series of open and closed circular catenated dimers with varying extents of intertwining between the monomer units, and then yielded, after decatenation, the supercoiled CC monomer. The replication patterns of two different minichromosomes were similar, although the LC form and the multiply intertwined dimers were much more evident in the smaller pAL4 than in pAL2. The same basic replication scheme was seen in vitro and in vivo but completion of polymerization and processing of the dimers were slower in vitro. Some radioactivity was detected in OC monomer early during replication, consistent with occasional decatenation of LC structures to produce OC molecules which then completed replication to form CC molecules. However, progression to CC catenated dimers prior to formation of CC monomers represented the major replication pathway.     

Replication of plasmid DNA in Proteus mirabilis in limiting concentrations of thymine.

Replicating forms of the R plasmid pRR12 and the colicin E1 plasmid RSF2124 were isolated from Proteus mirabilis after growth in medium containing a limiting concentration of thymine. Both plasmids were replicated as partially supercoiled intermediates, which have densities between the values of covalently closed circular and nicked circular plasmid DNA in ethidium bromide-cesium chloride gradients. In addition, both plasmids had replication intermediates, which have densities lower than that of linear P. mirabilis chromosomal DNA. Some structural features of these replication intermediates were examined.     

Synthesis of Superhelical Simian Virus 40 Deoxyribonucleic Acid in Cell Lysates*.

In vivo-labeled SV40 replicating DNA molecules can be converted into covalently closed superhelical SV40 DNA (SV40(I) using a lysate of sv40-infected monkey cells containing intact nuclei. Replication in vitro occurred at one-third the in vivo rate for 30 min at 30 degrees. After 1 hour of incubation, about 54% of the replicating molecules had been converted to SV40(I), 5% to nicked, circular molecules (SV40(II), 5% to covalently closed dimers; the remainder failed to complete replication although 75% of the prelabeled daughter strands had been elongated to one-genome length. Density labeling in vitro showed that all replicating molecules had participated during DNA synthesis in vitro. Velocity and equilibrium sedimentation analysis of pulse-chased and labeled DNA using radioactive and density labels suggested that SV40 DNA synthesis in vitro was a continuation of normal ongoing DNA synthesis. Initiation of new rounds of SV40 DNA replication was not detectable.     

Arrest of segregation leads to accumulation of highly intertwined catenated dimers: dissection of the final stages of SV40 DNA replication

When SV40-infected cells are placed into hypertonic medium, newly synthesized DNA accumulates as form C catenated dimers. These molecules consist of two supercoiled monomer circles of SV40 DNA interlocked by one or more topological inter-twinings and are seen as transiently labeled inter-mediates during normal replication. Form C catenated dimers represent pure segregation intermediates, replicative DNA structures in which DNA synthesis is complete but which still require topological separation of the two daughter circles. Hypertonic shock seems to block selectively a type II topoisomerase activity involved in disentangling the two circles. This is reflected in the fact that form C catenated dimers that accumulate during the block are highly intertwined with catenation linkage numbers up to C(L) = 20. While initiation of replication is also inhibited by hypertonic treatment, ongoing SV40 DNA synthesis is not affected, and replication is free to proceed from the earliest cairns structure through to form C catenated dimers. The block to segregation is rapidly and completely released by shifting the cells back to normal medium. A much slower recovery of DNA segregation takes place on prolonged incubation in hypertonic medium, perhaps because of some cellular homeostatic mechanism. The results of this work lead to a detailed view of the final stages of SV40 DNA replication.     

Separation of closed circular DNA from linear DNA by electrophoresis in two dimensions in agarose gels

A method that provides an easy, rapid, and reproducible way for separating closed circular DNA species from linear DNA and nicked circles is described. The method is based on the difference in mobility of form I (supercoiled) DNA and form II (nicked circles), and the differential mobility of relaxed circular DNA in the presence and absence of ethidium bromide (EtdBr). It can be used for detection or for purification of plasmid, episomal, or viral DNA from the bulk of cellular DNA, or from other DNA mixtures.     

Replicative intermediates in UV-irradiated simian virus 40

We have used Simian virus 40 (SV40) as a probe to study the replication of UV-damaged DNA in mammalian cells. Viral DNA replication in infected monkey kidney cells was synchronized by incubating a mutant of SV40 (tsA58) temperature-sensitive for the initiation of DNA synthesis at the restrictive temperature and then adding aphidicolin to temporarily inhibit DNA synthesis at the permissive temperature while permitting pre-replicative events to occur. After removal of the drug, the infected cells were irradiated at 100 J/m2 (254 nm) to produce 6-7 pyrimidine dimers per SV40 genome, and returned to the restrictive temperature to prevent reinitiation of replication from the SV40 origin. Replicative intermediates (RI) were labeled with [3H]thymidine, and isolated by centrifugation in CsCl/ethidium bromide gradients followed by BND-cellulose chromatography. The size distribution of daughter DNA strands in RI isolated shortly after irradiation was skewed towards lengths less than the interdimer spacing in parental DNA; this bias persisted for at least 1 h after irradiation, but disappeared within 3 h, by which time the size of the newly-synthesized DNA exceeded the interdimer distance. No significant excision of dimers from parental strands in either replicative intermediates or Form I (closed circular) DNA molecules was detected. These data are consistent with the hypothesis that replication forks are temporarily blocked by dimers encountered on the leading strand side of the fork, but that daughter strand continuity opposite dimers is eventually established. Evidence was obtained for the generation at late times after irradiation, of Form I molecules in which the daughter DNA strands contain dimers. Thus DNA strand exchange as well as trans-dimer synthesis may be involved in the generation of supercoiled Form I DNA from UV-damaged SV40 replicative intermediates.     

Molecular analysis of enhanced replication of UV-damaged simian virus 40 DNA in UV-treated mammalian cells.

Irradiation of simian virus 40 (SV40)-infected cells with low fluences of UV light (20 to 60 J/m2, inducing one to three pyrimidine dimers per SV40 genome) causes a dramatic inhibition of viral DNA replication. However, treatment of cells with UV radiation (20 J/m2) before infection with SV40 virus enhances the replication of UV-damaged viral DNA. To investigate the mechanism of this enhancement of replication, we analyzed the kinetics of synthesis and interconversion of viral replicative intermediates synthesized after UV irradiation of SV40-infected cells that had been pretreated with UV radiation. This enhancement did not appear to be due to an expansion of the size of the pool of replicative intermediates after irradiation of pretreated infected cells; the kinetics of incorporation of labeled thymidine into replicative intermediates were very similar after irradiation of infected control and pretreated cells. The major products of replication of SV40 DNA after UV irradiation at the low UV fluences used here were form II molecules with single-stranded gaps (relaxed circular intermediates). There did not appear to be a change in the proportion of these molecules synthesized when cells were pretreated with UV radiation. Thus, it is unlikely that a substantial amount of DNA synthesis occurs past pyrimidine dimers without leaving gaps. This conclusion is supported by the observation that the proportion of newly synthesized SV40 form I molecules that contain pyrimidine dimers was not increased in pretreated cells. Pulse-chase experiments suggested that there is a more efficient conversion of replicative intermediates into form I molecules in pretreated cells. This could be due to more efficient gap filling in relaxed circular intermediate molecules or to the release of blocked replication forks. Alternatively, the enhanced replication observed here may be due to an increase in the excision repair capacity of the pretreated cells.     

Specificity of the endonuclease activity of the baculovirus alkaline nuclease for single-stranded DNA

The Autographa californica multiple nucleocapsid nucleopolyhedrovirus (AcMNPV) alkaline nuclease (AN) likely participates in the maturation of virus genomes and in DNA recombination. AcMNPV AN was expressed in a recombinant baculovirus as a His -tagged fusion and obtained in pure form (*AN) or as a (6)complex with the baculoviral single-stranded DNA-binding protein LEF-3 (*AN/L3). Both AN preparations possessed potent 5' --> 3'-exonuclease and weak endonuclease activities. Mutant *AN(S146A)/L3 with a change from serine to alanine at position 146 in a conservative motif was impaired in both activities. This proved that the endonuclease is an intrinsic activity of baculovirus AN. The AN endonuclease showed specificity for single-stranded DNA and converted supercoiled plasmid DNA (replicative form I, RFI) into the open circular form (RFII) by a single strand break. Plasmid DNA relaxed with topoisomerase I was resistant to *AN/L3 indicating that the partially single-stranded regions in negatively supercoiled molecules served as targets for the endonuclease. Unwinding the supercoiled DNA with ethidium bromide also made DNA resistant to AN/L3. In reactions with nicked circular DNA (RFII), AN and AN/L3 hydrolyzed exonucleolytically the broken strand or cut endonucleolytically the intact strand at the position opposite the nick (gap). When LEF-3 was added to the assay, the balance between the exonucleolytic and endonucleolytic modes of hydrolysis shifted in favor of the exonuclease. The data suggest that the AN endonuclease may digest the intermediates in replication and recombination at positions of structural irregularities in DNA duplexes, whereas LEF-3 may further regulate processing of the intermediates by AN via the endonuclease and exonuclease pathways.     

The Bacillus subtilis primosomal protein DnaD untwists supercoiled DNA

The essential Bacillus subtilis DnaD and DnaB proteins have been implicated in the initiation of DNA replication. Recently, DNA remodeling activities associated with both proteins were discovered that could provide a link between global or local nucleoid remodeling and initiation of replication. DnaD forms scaffolds and opens up supercoiled plasmids without nicking to form open circular complexes, while DnaB acts as a lateral compaction protein. Here we show that DnaD-mediated opening of supercoiled plasmids is accompanied by significant untwisting of DNA. The net result is the conversion of writhe (Wr) into negative twist (Tw), thus maintaining the linking number (Lk) constant. These changes in supercoiling will reduce the considerable energy required to open up closed circular plectonemic DNA and may be significant in the priming of DNA replication. By comparison, DnaB does not affect significantly the supercoiling of plasmids. Binding of the DnaD C-terminal domain (Cd) to DNA is not sufficient to convert Wr into negative Tw, implying that the formation of scaffolds is essential for duplex untwisting. Overall, our data suggest that the topological effects of the two proteins on supercoiled DNA are different; DnaD opens up, untwists and converts plectonemic DNA to a more paranemic form, whereas DnaB does not affect supercoiling significantly and condenses DNA only via its lateral compaction activity. The significance of these findings in the initiation of DNA replication is discussed.     

Replication of DNA minicircles in kinetoplasts isolated from Crithidia fasciculata: structure of nascent minicircles.

We have previously described an isolated kinetoplast system from Crithidia fasciculata capable of ATP-dependent replication of kinetoplast DNA minicircles (L. Birkenmeyer and D.S. Ray, J. Biol. Chem. 261: 2362-2368, 1986). We present here the identification of two new minicircle species observed in short pulse-labeling experiments in this system. The earliest labeled minicircle species (component A) contains both nascent H and L strands and is heterogeneous in sedimentation and electrophoretic migration. Component A has characteristics consistent with a Cairns-type structure in which the L strand is the leading strand and the H strand is the lagging strand. The other new species (component B) has a nascent 2.5-kilobase linear L strand with a single discontinuity that mapped to either of two alternative origins located 180 degrees apart on the minicircle map. Component B could be repaired to a covalently closed form by Escherichia coli polymerase I and T4 ligase but not by T4 polymerase and T4 ligase. Even though component B has a single gap in one strand, it had an electrophoretic mobility on an agarose gel (minus ethidium bromide) similar to that of a supercoiled circle with three supertwists. Treatment of component B with topoisomerase II converted it to a form that comigrated with a nicked open circular form (replicative form II). These results indicate that component B is a knotted topoisomer of a kinetoplast DNA minicircle with a single gap in the L strand.     

Importance of state of methylation of oriC GATC sites in initiation of DNA replication in Escherichia coli.

In vivo and in vitro evidence is presented implicating a function of GATC methylation in the Escherichia coli replication origin, oriC, during initiation of DNA synthesis. Transformation frequencies of oriC plasmids into E. coli dam mutants, deficient in the GATC-specific DNA methylase, are greatly reduced compared with parental dam+ cells, particularly for plasmids that must use oriC for initiation. Mutations that suppress the mismatch repair deficiency of dam mutants do not increase these low transformation frequencies, implicating a new function for the Dam methylase. oriC DNA isolated from dam- cells functions 2- to 4-fold less well in the oriC-specific in vitro initiation system when compared with oriC DNA from dam+ cells. This decreased template activity is restored 2- to 3-fold if the DNA from dam- cells is first methylated with purified Dam methylase. Bacterial origin plasmids or M13-oriC chimeric phage DNA, isolated from either base substitution or insertion dam mutants of E. coli, exhibit some sensitivity to digestion by DpnI, a restriction endonuclease specific for methylated GATC sites, showing that these dam mutants retain some Dam methylation activity. Sites of preferred cleavage are found within the oriC region, as well as in the ColE1-type origin.     

Complete replication of templates by Escherichia coli DNA polymerase III holoenzyme

DNA polymerase III holoenzyme (holoenzyme) processively and rapidly replicates a primed single-stranded DNA circle to produce a duplex with an interruption in the synthetic strand. The precise nature of this discontinuity in the replicative form (RF II) and the influence of the 5' termini of the DNA and RNA primers were analyzed in this study. Virtually all (90%) of the RF II products primed by DNA were nicked structures sealable by Escherichia coli DNA ligase; in 10% of the products, replication proceeded one nucleotide beyond the 5' DNA terminus displacing (but not removing) the 5' terminal nucleotide. With RNA primers, replication generally went beyond the available single-stranded template. The 5' RNA terminus was displaced by 1-5 nucleotides in 85% of the products; a minority of products was nicked (9%) or had short gaps (6%). Termination of synthesis on a linear DNA template was usually (85%) one base shy of completion. Thus, replication by holoenzyme utilizes all, or nearly all, of the available template and shows no significant 5'----3' exonuclease action as observed in primer removal by the "nick-translation" activity of DNA polymerase I.     

Extensive unwinding of the plasmid template during staged enzymatic initiation of DNA replication from the origin of the Escherichia coli chromosome

Early in the staged initiation of enzymatic replication of plasmids containing the unique origin of the E. coli chromosome (oriC), the plasmid is converted to a new topological form which is highly underwound, two to 15 times more than native supercoiled DNA. The underwinding reaction precedes priming of DNA synthesis and follows an initial complex formation, requiring ATP and proteins dnaA, dnaB, and dnaC; underwinding depends on the further addition of gyrase and SSB. DnaB protein as a helicase and gyrase as a topoisomerase drive the underwinding with the energy of ATP hydrolysis. The underwound template, extensively single-stranded and complexed with proteins, is an active form for priming by primase and elongation by DNA polymerase III holoenzyme.     

Escherichia coli topoisomerase I can segregate replicating pBR322 daughter DNA molecules in vitro

The reconstituted pBR322 DNA replication system has been used to identify a mechanism for the processing and segregation of daughter DNA molecules by Escherichia coli topoisomerase I (Topo I) during the terminal stages of DNA replication. At low concentrations of Topo I (sufficient to confer specificity to the replication system for DNA templates containing a ColE1-type origin of DNA replication), the major products of the replication reaction were: multigenome-length, linear, double-stranded DNA molecules (an aberrant product); multiply interlinked, catenated, supercoiled DNA dimers; and a last Cairns-type replication intermediate. Thirty- to fifty-fold higher concentrations of Topo I led to the appearance of form II and form I pBR322 DNA as the only synthetic products. A model was developed in which Topo I, bound to a single-stranded gap on the parental H strand DNA just upstream of the origin of DNA replication, catalyzed the decatenation of the intermolecular linkages between the two daughter DNA molecules that were generated by primosome-catalyzed unwinding of the residual nonreplicated parental duplex DNA in the last Cairns-type intermediate. At low concentrations of Topo I, however, the intermolecular linkages persisted and, within the context of this replication system, were not removed by DNA gyrase. In support of this model it was demonstrated that: there was a single-stranded gap between the nonreplicated parental duplex region and the 5' end of the nascent leading-strand DNA; the number of intermolecular linkages in the catenated supercoiled DNA dimers was inversely related to the concentration of Topo I; the supercoiled DNA dimers did not serve as a precursor of the final form I DNA product; and maturation of the last Cairns-type replication intermediate to form I DNA was not affected by the presence of coumermycin, a potent inhibitor of the activities of DNA gyrase.     

Mode of replication of the conjugative R-plasmid RSF1040 in Escherichia coli.

Replicating deoxyribonucleic acid (DNA) molecules of plasmid RSF1040, a deletion mutant of the conjugative R plasmid R6K, appear in the electron microscope as partially supercoiled structures with two open circular branches of equal size, although open structures with three branches, two branching points and no supercoiled regions (theta structures) were also found at a lower frequency. The partially supercoiled molecules sediment more rapidly than native covalently closed circular DNA in neutral sucrose gradients and band at a position intermediate between covalently closed circular and open circular DNA in CsClethidium bromide gradients. Electron microscope measurements of the linear EcoRI-treated replicative intermediates indicate that replication can be initiated at two sites (origins) on the plasmid DNA molecule located at about 23% (alpha) and 39% (beta) of the total genome length from an EcoRI end designated arbitrarily as the "left-hand" end of the molecule. The overall replication of RSF1040 is asymmetrically bidirectional. Replication from the alpha origin proceeds first to the "right" to a unique termination site located some 55% of the total genome length from the left-hand end of the molecule. At this point replication proceeds from the alpha origin to the "left" (i.e., opposite to the original direction of replication) until replication of the molecule is completed. Replication also proceeds from the beta origin asymmetrically to the unique terminus site.     

The termination region for SV40 DNA replication directs the mode of separation for the two sibling molecules

Separation of the two newly replicated chromosomes in simian virus 40 late replicating intermediates (RI*) occurred by two pathways. The parental DNA strands were completely unwound, releasing circular DNA monomers with a gap in the nascent strand (Form II*), or duplex DNA in the termination region was not unwound, resulting in formation of catenated dimers. Under optimal conditions, both products were transient intermediates in replication, although Form II* was predominant. However, in hypertonic medium both RI* and catenated dimers accumulated, and Form II* was not observed. Hypertonic medium appeared to inhibit both DNA unwinding in the termination region and separation of catenated dimers. When the size of the genome or the position of the origin of replication was changed, termination occurred at sites other than that of wild-type SV40. Neither catenated dimers nor RI* DNA accumulated at these sites. Instead, RI* separated into Form II*. Unwinding parental DNA was more difficult at some termination regions than others. Therefore, although completion of DNA replication does not require a unique termination sequence, this sequence can determine the mode of separation for sibling molecules.     

Initiation of SV40 DNA replication after microinjection into Xenopus eggs

We have examined the capacity of Xenopus laevis eggs to support replication of microinjected SV40 DNA. As previously reported, microinjected DNA undergoes semi-conservative replication. Unlabeled SV40 DNA was microinjected with [³H]dTTP and, after a 3 h incubation period, the DNA was recovered and adsorbed to BND-cellulose. Elution with an NaCl gradient removes molecules that are entirely double-stranded but not those with single-stranded regions. The latter DNA population is eluted with caffeine. The radioactive DNA that eluted with NaCl was comprised mostly of supercoiled and open circular SV40 DNAs. The radioactive DNA eluted with caffeine was comprised mainly of endogenous DNA but also contained replicative forms of SV40 DNA. Analysis of SV40 DNA replication intermediates by electron microscopy revealed mainly Cairn's forms of varying degrees of maturation. Digestion with BamH1, which cleaves SV40 DNA almost opposite the normal viral replication origin, indicated that SV40 DNA microinjected into frog eggs does not initiate DNA synthesis at its normal initiation site nor at any other obvious preferred site. Rather, it appears that when this template is injected into activated Xenopus eggs, replication may initiate at random.     

Complete enzymatic synthesis of DNA containing the SV40 origin of replication

The replication of simian virus 40 origin-containing DNA has been reconstituted in vitro with SV40 large T antigen and purified proteins isolated from HeLa cells. Covalently closed circular DNA (RF I') daughter molecules are formed in the presence of T antigen, a single-stranded DNA binding protein and DNA polymerase alpha-primase complex, together with ribonuclease H, DNA ligase, topoisomerase II, and a double-stranded specific exonuclease that has been purified to homogeneity. The 44-kDa exonuclease-digested oligo(rA) annealed to poly(dT) in the 5'----3' direction. DNA ligase and the 5'----3' exonuclease were essential for RF I' formation. Covalently closed circular duplex DNA and full length linear single-stranded DNA were detected by alkaline gel electrophoresis as products of the complete system. DNA replication in the absence of either DNA ligase or the 5'----3' exonuclease yielded DNA products that were half length (approximately 1500 nucleotides) and smaller Okazaki-like fragments (approximately 200 nucleotides). Hybridization experiments showed that the longer chains were synthesized from the leading strand template, while the small products were synthesized from the lagging strand template. These results suggest that the RNA primers attached to 5' ends of replicated DNA are completely removed by the 5'----3' exonuclease, with the assistance of RNase H.