Segregation of relaxed replicated dimers when DNA ligase and DNA polymerase I are limited during oriC-specific DNA replication.

An in vitro Escherichia coli oriC-specific DNA replication system was used to investigate the DNA replication pathways of oriC plasmids. When this system was perturbed by the DNA ligase inhibitor nicotinamide mononucleotide (NMN), alterations occurred in the initiation of DNA synthesis and processing of intermediates and DNA products. Addition of high concentrations of NMN soon after initiation resulted in the accumulation of open circular dimers (OC-OC). These dimers were decatenated to open circular monomers (form II or OC), which were then processed to closed circular supercoiled monomers (form I or CC) products. After a delay, limited ligation of the interlinked dimers (OC-OC to CC-OC and CC-CC) also occurred. Similar results were obtained with replication protein extracts from polA mutants. The presence of NMN before any initiation events took place prolonged the existence of nicked template DNA and promoted, without a lag period, limited incorporation into form II molecules. This DNA synthesis was nonspecific with respect to oriC, as judged by DnaA protein dependence, and presumably occurred at nicks in the template DNA. These results are consistent with oriC-specific initiation requiring closed supercoiled molecules dependent on DNA ligase activity. The results also show that decatenation of dimers occurs readily on nicked dimer and represents an efficient pathway for processing replication intermediates in vitro.     

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.     

In vitro assembly of a prepriming complex at the origin of the Escherichia coli chromosome

During initiation of DNA replication of plasmids containing the origin of the Escherichia coli chromosome (oriC), the proteins dnaA, dnaB, and dnaC interact and assemble a complex at oriC. The complex is larger and more asymmetric than that formed by dnaA protein and embraces an extra 50 base pairs at the left side of the minimal oriC sequence. Both dnaA and dnaB proteins have been identified in the complex by electron microscopy and antibody binding; dnaC protein was not detected. HU protein, which stimulates the activity of the initiation reaction, was often present. Entry of dnaB protein required dnaA and dnaC proteins and a supercoiled template. Thus, a complex structure, involving multiple proteins and a large region of DNA, must be formed at the origin to prepare the template for priming and replication.     

MobB protein stimulates nicking at the R1162 origin of transfer by increasing the proportion of complexed plasmid DNA.

An essential early step in conjugal mobilization of R1162, nicking of the DNA strand that is subsequently transferred, is carried out in the relaxosome, a complex of two plasmid-encoded proteins and DNA at the origin of transfer (oriT). A third protein, MobB, is also required for efficient mobilization. We show that in the cell this protein increases the proportion of molecules specifically nicked at oriT, resulting in lower yields of covalently closed molecules after alkaline extraction. These nicked molecules largely remain supercoiled, with unwinding presumably constrained by the relaxosome. MobB enhances the sensitivity of the oriT DNA to oxidation by permanganate, indicating that the protein acts by increasing the fraction of complexed molecules. Mutations that significantly reduce the amount of complexed DNA in the cell were isolated. However, plasmids with these mutations were mobilized at nearly the normal frequency, were nicked at a commensurate level, and still required MobB. Our results indicate that the frequency of transfer is determined both by the amount of time each molecule is in the nicked form and by the proportion of complexed molecules in the total population.     

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.     

IHF redistributes bound initiator protein, DnaA, on supercoiled oriC of Escherichia coli

In Escherichia coli, initiation of chromosome replication requires that DnaA binds to R boxes (9-mer repeats) in oriC, the unique chromosomal replication origin. At the time of initiation, integration host factor (IHF) also binds to a specific site in oriC. IHF stimulates open complex formation by DnaA on supercoiled oriC in cell-free replication systems, but it is unclear whether this stimulation involves specific changes in the oriC nucleoprotein complex. Using dimethylsulphate (DMS) footprinting on supercoiled oriC plasmids, we observed that IHF redistributed prebound DnaA, stimulating binding to sites R2, R3 and R5(M), as well as to three previously unidentified non-R sites with consensus sequence (A/T)G(G/C) (A/T)N(G/C)G(A/T)(A/T)(T/C)A. Redistribution was dependent on IHF binding to its cognate site and also required a functional R4 box. By reducing the DnaA level required to separate DNA strands and trigger initiation of DNA replication at each origin, IHF eliminates competition between strong and weak sites for free DnaA and enhances the precision of initiation synchrony during the cell cycle.     

Electrophoretic mobility of supercoiled,catenated and knotted DNA molecules

We systematically varied conditions of two-dimensional (2D) agarose gel electrophoresis to optimize separation of DNA topoisomers that differ either by the extent of knotting, the extent of catenation or the extent of supercoiling. To this aim we compared electrophoretic behavior of three different families of DNA topoisomers: (i) supercoiled DNA molecules, where supercoiling covered the range extending from covalently closed relaxed up to naturally supercoiled DNA molecules; (ii) postreplicative catenanes with catenation number increasing from 1 to ∼15, where both catenated rings were nicked; (iii) knotted but nicked DNA molecules with a naturally arising spectrum of knots. For better comparison, we studied topoisomer families where each member had the same total molecular mass. For knotted and supercoiled molecules, we analyzed dimeric plasmids whereas catenanes were composed of monomeric forms of the same plasmid. We observed that catenated, knotted and supercoiled families of topoisomers showed different reactions to changes of agarose concentration and voltage during electrophoresis. These differences permitted us to optimize conditions for their separation and shed light on physical characteristics of these different types of DNA topoisomers during electrophoresis.     

Topoisomerase I confers specificity in enzymatic replication of the Escherichia coli chromosomal origin

Crude soluble enzyme fractions that initiate bidirectional replication from the unique Escherichia coli chromosomal origin (oriC) have been fractionated further to identify the components and mechanisms of this complex system. Among the necessary factors is a class of specificity proteins that suppress initiations on plasmids which lack the oriC sequence and which do not depend on dnaA protein. One such specificity factor has been identified as RNase H (Ogawa, T., Pickett, G. G., Kogoma, T., and Kornberg, A. (1984) Proc. Natl. Acad. Sci. U. S. A. 81, 1040-1044). Another, described here, has proved to be topoisomerase I. A protein was purified to near homogeneity based on assays of (i) inhibition of the replication of plasmids (and other supercoiled DNA) lacking oriC and (ii) conferral of dnaA protein dependence on the replication of an oriC plasmid. This specificity protein is indistinguishable from authentic E. coli topoisomerase I by several criteria: (i) molecular weight under denaturing conditions, (ii) relaxation activity on negatively supercoiled DNA, (iii) cleavage pattern of single-stranded DNA, (iv) specificity factor activity, and (v) neutralization of activity by antibody against topoisomerase I. One possible mechanism of the specificity action of topoisomerase I is destabilization of primers for replication except when they are preserved at an oriC sequence bound by dnaA protein and other replication proteins.     

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.     

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.     

Mechanisms of replication and telomere resolution of the linear plasmid prophage N15

The prophage of coliphage N15 is not integrated into the bacterial chromosome but exists as a linear plasmid molecule with covalently closed ends. Upon infection of an Escherichia coli cell, the phage DNA circularizes via cohensive ends. A phage-encoded enzyme, protelomerase, then cuts at another site, telRL, and forms hairpin ends (telomeres). Purified protelomerase alone processes circular and linear plasmid DNA containing the target site telRL to produce linear double-stranded DNA with covalently closed ends in vitro. N15 protelomerase is necessary for replication of the linear prophage through its action as a telomere-resolving enzyme. Replication of circular N15-based miniplasmids requires the only gene repA that encodes multidomain protein homologous to replication proteins of bacterial plasmids replicated by theta-mechanism, particularly, phage P4 alpha-replication protein. Replication of the N15 prophage is initiated at an internal ori site located within repA. Bidirectional replication results in formation of the circular head-to-head, tail-to-tail dimer molecule. Then the N15 protelomerase cuts both duplicated telomeres generating two linear plasmid molecules with covalently closed ends. The N15 prophage replication thus appears to follow the mechanism distinct from that employed by poxviruses and could serve as a model for other prokaryotic replicons with hairpin ends, and particularly, for linear plasmids and chromosomes of Borrelia burgdorferi.     

Gene A protein cleavage of recombinant plasmids containing the phi X174 replication origin

Synthetic oligonucleotides, DNA ligase and DNA polymerase were used to construct double-stranded DNA fragments homologous to the first 25, 27 or 30 b.p. of the origin of replication of bacteriophage phi X174 (nucleotides 4299-4328 of the phi X174 DNA sequence). The double-stranded DNA fragments were cloned into the unique SmaI or HindIII restriction sites in the kanamycin-resistance gene of pACYC177 (AmpR, KmR). Recombinant plasmids were picked up by colony hybridization. DNA sequencing showed that not only recombinant plasmids with the expected insert were formed, but also recombinant plasmids with a shorter insert. Recombinant plasmids with an insert homologous to the first 24, 25, 26, 27, 28 or all 30 b.p. of the phi X174 origin region were thus obtained. Supercoiled plasmids containing a sequence homologous to the first 27, 28 or 30 b.p. of the phi X174 origin region are nicked by the phi X174 gene A protein. However, the other supercoiled plasmids are not nicked by the phi X174 gene A protein. These results show that the first 27 b.p. of the phi X174 origin region are sufficient as well as required for the initiation step in phi X174 RF DNA replication, i.e. the cleavage by gene A protein.     

Effects of the antitumor drug VP16 (etoposide) on the archaebacterial Halobacterium GRB 1.7 kb plasmid in vivo.

The topoprofile of 1.7 kb plasmids from the archaebacterium Halobacterium GRB was analysed from cells growing with or without VP16 (etoposide). This drug interferes with the breakage-reunion reaction of eukaryotic DNA topoisomerase II by inhibiting the ligase activity of this enzyme. Addition of VP16 to the culture medium of Halobacterium GRB cells results in the introduction of single- and double-strand DNA breaks in part of the plasmid population, with proteins covalently associated at their 5' ends. While some of the remaining covalently closed circular DNA molecules are relaxed, VP16 treatment also gives rise to the production of positively supercoiled 1.7 kb plasmids. In contrast to adriamycin, VP16 does not intercalate into the 1.7 kb plasmid DNA in vivo. These results suggest that the VP16 target in halobacteria is a DNA topoisomerase II. Three major cleavage sites were detected on the 1.7 kb plasmid after VP16 treatment in vivo.     

Mapping of the in vivo start site for leading strand DNA synthesis in plasmid R1.

We have previously constructed Escherichia coli strains in which an R1 plasmid is integrated into the origin of chromosome replication, oriC. In such intR1 strains, oriC is inactive and initiation of chromosome replication instead takes place at the integrated R1 origin. Due to the large size of the chromosome, replication intermediates generated at the R1 origin in these strains are considerably more long-lived than those in unintegrated R1 plasmids. We have taken advantage of this and performed primer extensions on total DNA isolated from intR1 strains, and mapped the free 5' DNA ends that were generated as replication intermediates during R1 replication in vivo. The sensitivity of the mapping was considerably improved by the use of a repeated primer extension method (RPE). The free DNA ends were assumed to represent normal in vivo start sites for leading strand DNA synthesis in plasmid R1. The ends were mapped to a short region approximately 380 bp away from the R1 minimal origin, and the positions agreed well with previous in vitro mappings. The same start positions were also utilized in the absence of the DnaA protein, indicating that DnaA is not required for determination of the position at which DNA synthesis starts during initiation of replication at the R1 origin.     

Bidirectional replication from an internal ori site of the linear N15 plasmid prophage

The prophage of coliphage N15 is not integrated into the chromosome but exists as a linear plasmid molecule with covalently closed hairpin ends (telomeres). Upon infection the injected phage DNA circularizes via its cohesive ends. Then, a phage-encoded enzyme, protelomerase, cuts the circle and forms the hairpin telomeres. N15 protelomerase acts as a telomere-resolving enzyme during prophage DNA replication. We characterized the N15 replicon and found that replication of circular N15 miniplasmids requires only the repA gene, which encodes a multidomain protein homologous to replication proteins of bacterial plasmids replicated by a theta-mechanism. Replication of a linear N15 miniplasmid also requires the protelomerase gene and telomere regions. N15 prophage replication is initiated at an internal ori site located within repA and proceeds bidirectionally. Electron microscopy data suggest that after duplication of the left telomere, protelomerase cuts this site generating Y-shaped molecules. Full replication of the molecule and subsequent resolution of the right telomere then results in two linear plasmid molecules. N15 prophage replication thus appears to follow a mechanism that is distinct from that employed by eukaryotic replicons with this type of telomere and suggests the possibility of evolutionarily independent appearances of prokaryotic and eukaryotic replicons with covalently closed telomeres.     

Escherichia coli prereplication complex assembly is regulated by dynamic interplay among Fis, IHF and DnaA

Initiator DnaA and DNA bending proteins, Fis and IHF, comprise prereplication complexes (pre-RC) that unwind the Escherichia coli chromosome's origin of replication, oriC. Loss of either Fis or IHF perturbs synchronous initiation from oriC copies in rapidly growing E. coli. Based on dimethylsulphate (DMS) footprinting of purified proteins, we observed a dynamic interplay among Fis, IHF and DnaA on supercoiled oriC templates. Low levels of Fis inhibited oriC unwinding by blocking both IHF and DnaA binding to low affinity sites. As the concentration of DnaA was increased, Fis repression was relieved and IHF rapidly redistributed DnaA to all unfilled binding sites on oriC. This behaviour in vitro is analogous to observed assembly of pre-RC in synchronized E. coli. We propose that as new DnaA is synthesized in E. coli, opposing activities of Fis and IHF ensure an abrupt transition from a repressed complex with unfilled weak affinity DnaA binding sites to a completely loaded unwound complex, increasing both the precision of DNA replication timing and initiation synchrony.     

Initiation signals for the conversion of single stranded to double stranded DNA forms in the streptococcal plasmid pLS1.

We have characterized a region in the streptococcal plasmid pLS1 located between nucleotides 4103 and 4218 which is a signal involved in the conversion of single stranded intermediates of replication to double stranded plasmid forms. This region has a large axis of dyad symmetry resulting in the formation of a secondary structure as revealed by the location of endonuclease S1-cleavage sites in supercoiled covalently closed circular pLS1 DNA. Deletions affecting this region caused a fivefold reduction in plasmid copy number, plasmid instability and the accumulation of single-stranded DNA intermediates. The conversion signal of pLS1 has homologues in other staphylococcal plasmids, sharing a consensus sequence located in the loop of the signal. Computer assisted analysis showed that the signal detected in pLS1 has a high degree of homology with the complementary strand origin of the Escherichia coli single stranded bacteriophages phi X174 and M13.     

The structure of replicating kinetoplast DNA networks

Kinetoplast DNA (kDNA), the mitochondrial DNA of Crithidia fasciculata and related trypanosomatids, is a network containing approximately 5,000 covalently closed minicircles which are topologically interlocked. kDNA synthesis involves release of covalently closed minicircles from the network, and, after replication of the free minicircles, reattachment of the nicked or gapped progeny minicircles to the network periphery. We have investigated this process by electron microscopy of networks at different stages of replication. The distribution of nicked and closed minicircles is easily detectable either by autoradiography of networks radiolabeled at endogenous nicks by nick translation or by twisting the covalently closed minicircles with intercalating dye. The location of newly synthesized minicircles within the network is determined by autoradiography of network is determined by autoradiography of networks labeled in vivo with a pulse of [3H]thymidine. These studies have clarified structural changes in the network during replication, the timing of repair of nicked minicircles after replication, and the mechanism of division of the network.     

Rapid purification of covalently closed circular DNAs of bacterial plasmids and animal tumor viruses

A rapid and simple purification of covalently closed circular (supercoiled) DNA from both bacterial clones (plasmids) and African green monkey cells (SV40) is presented. The method involves immediate treatment of lysed cells with sodium hydroxide, followed by neutralization and phenol extraction in high salt. After the extraction mixture is centrifuged, supercoiled DNA is found in the aqueous phase, the noncovalently closed DNA molecules form a white precipitate at the interphase, and proteins pellet. Contaminating RNA is eliminated from the aqueous phase by RNAse treatment and precipitation of the supercoiled DNA with polyethylene glycol. Residual polyethylene glycol is removed from the resuspended DNA by chloroform extraction. The purified supercoiled DNA is compatible with restriction enzymes, and is efficient at transforming both _χ1776 and HB101 bacterial hosts. Centrifugation in ethidium bromide-cesium chloride or sucrose gradients is not necessary. The method is virtually independent of the molecular size and gives good yields of supercoiled DNA. The technique is applicable to large-scale preparations and as a rapid “screening” procedure in which 20 to 30 samples can be easily purified within 5 to 6 h.