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.     

DNA gyrase-catalyzed decatenation of multiply linked DNA dimers

One possible intermediate during the terminal stages of the replication of a closed circular DNA is a catenated DNA dimer of the two completed daughter molecules. The two monomer DNA rings in these DNA dimers can be linked as many as 20-30 times. In Escherichia coli, DNA gyrase could act on these catenated dimers to eliminate the linkages between the daughter duplexes, yielding the final monomer product. In this report, this reaction has been studied biochemically. The in vitro pBR322 DNA replication system (Minden, J., and Marians, K. J. (1985) J. Biol. Chem. 260, 9316-9325) was used to manufacture large amounts of multiply linked catenated DNA dimers for use as a substrate for DNA gyrase-catalyzed decatenation. Studies presented here demonstrate that this decatenation reaction is more efficient with supercoiled as opposed to relaxed DNA dimers, proceeds in a distributive fashion, is inhibited by moderate amounts of salt (80 mM KCl), and is stimulated by the E. coli protein HU.     

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.     

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.     

Decatenation of DNA circles by FtsK-dependent Xer site-specific recombination

DNA replication results in interlinked (catenated) sister duplex molecules as a consequence of the intertwined helices that comprise duplex DNA. DNA topoisomerases play key roles in decatenation. We demonstrate a novel, efficient and directional decatenation process in vitro, which uses the combination of the Escherichia coli XerCD site-specific recombination system and a protein, FtsK, which facilitates simple synapsis of dif recombination sites during its translocation along DNA. We propose that the FtsK-XerCD recombination machinery, which converts chromosomal dimers to monomers, may also function in vivo in removing the final catenation links remaining upon completion of DNA replication.     

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.     

Topoisomerase inhibitors can selectively interfere with different stages of simian virus 40 DNA replication.

I have found that antineoplastic drugs which are known to be inhibitors of mammalian DNA topoisomerases have pronounced and selective effects on simian virus 40 DNA replication. Ellipticine, 4'-(9-acridinylamino)methanesulfon-m-aniside, and Adriamycin blocked decatenation of newly replicated simian virus 40 daughter chromosomes in vivo. The arrested decatenation intermediates produced by these drugs contained single-strand DNA breaks. Ellipticine in particular produced these catenated dimers rapidly and efficiently. Removal of the drug resulted in rapid reversal of the block and completion of decatenation. The demonstration that these drugs interfere with decatenation suggests that they may exert their cytotoxic and antineoplastic effects by preventing the separation of newly replicated cellular chromosomes. Camptothecin rapidly breaks replication forks in growing Cairns structures. It is likely that the target of camptothecin is the "swivel" topoisomerase required for DNA replication and that it is located at or very near the replication fork in vivo. Evidence is presented that many of the broken Cairns structures are in fact half-completed sister chromatid exchanges. One pathway for the resolution of these structures is completion of the sister chromatid exchange to produce a circular head-to-tail dimer.     

Kinetics of minichromosome replication in Escherichia coli B/r.

Replication control of the minichromosome pAL2 was found to differ from that of the chromosome in synchronously dividing populations of Escherichia coli B/r. Initiation of minichromosome replication took place at an increasing rate throughout synchronous growth. No coupling to initiation of chromosome replication was detected. Minichromosome replication was further examined in a dnaA5(Ts) temperature-sensitive initiation mutant. When cultures held at nonpermissive temperature (41 degrees C) for 60 min were shifted to permissive temperature (25 degrees C), initiation of both pAL2 and chromosome replication ensued in two waves spaced 25 to 35 min apart. Evidence is presented that minichromosomes terminate replication by passing slowly through a series of dimeric intermediate forms before reaching the closed circular monomeric form. The consequence of this slow passage as a rate-limiting step in the initiation reaction is discussed.     

A catenated intermediate in plasmid replication

An intermediate in the replication of three different staphylococcal plasmids is a catenated mixed dimer consisting of an open circular and a closed circular monomer. The mixed dimer, having a buoyant density intermediate between that of circular duplex and relaxed DNA's in dye-buoyant density gradients is rapidly and transiently labeled and appears to be a precursor of mature closed circular monomers. Whether it is an obligatory intermediate or a step on an alternate replication pathway remains uncertain.     

Effect of ICRF-193, a novel DNA topoisomerase II inhibitor, on simian virus 40 DNA and chromosome replication in vitro.

The effect of ICRF-193, a noncleavable-complex-forming topoisomerase II inhibitor, on simian virus 40 (SV40) DNA and SV40 chromosome replication was examined by using an in vitro replication system composed of HeLa cell extracts and SV40 T antigen. Unlike the topoisomerase inhibitors VP-16 and camptothecin, ICRF-193 had little effect on DNA chain elongation during SV40 DNA replication, but high-molecular-weight DNAs instead of segregated monomer DNAs accumulated as major products. Analysis of the high-molecular-weight DNAs by two-dimensional gel electrophoresis revealed that they consisted of catenated dimers and late Cairns-type DNAs. Incubation of the replicated DNA with topoisomerase II resulted in conversion of the catenated dimers to monomer DNAs. These results indicate that ICRF-193 induces accumulation of catenated dimers and late Cairns-type DNAs by blocking the decatenating and relaxing activities of topoisomerase II in the late stage of SV40 DNA replication. In contrast, DNA replication of SV40 chromosomes was severely blocked by ICRF-193 at the late stage, and no catenated dimers were synthesized. These results are consistent with the finding that topoisomerase II is required for unwinding of the final duplex DNA in the late stage of SV40 chromosome replication in vitro.     

How topoisomerase IV can efficiently unknot and decatenate negatively supercoiled DNA molecules without causing their torsional relaxation

Freshly replicated DNA molecules initially form multiply interlinked right-handed catenanes. In bacteria, these catenated molecules become supercoiled by DNA gyrase before they undergo a complete decatenation by topoisomerase IV (Topo IV). Topo IV is also involved in the unknotting of supercoiled DNA molecules. Using Metropolis Monte Carlo simulations, we investigate the shapes of supercoiled DNA molecules that are either knotted or catenated. We are especially interested in understanding how Topo IV can unknot right-handed knots and decatenate right-handed catenanes without acting on right-handed plectonemes in negatively supercoiled DNA molecules. To this end, we investigate how the topological consequences of intersegmental passages depend on the geometry of the DNA-DNA juxtapositions at which these passages occur. We observe that there are interesting differences between the geometries of DNA-DNA juxtapositions in the interwound portions and in the knotted or catenated portions of the studied molecules. In particular, in negatively supercoiled, multiply interlinked, right-handed catenanes, we detect specific regions where DNA segments belonging to two freshly replicated sister DNA molecules form left-handed crossings. We propose that, due to its geometrical preference to act on left-handed crossings, Topo IV can specifically unknot supercoiled DNA, as well as decatenate postreplicative catenanes, without causing their torsional relaxation.     

A catenated DNA molecule as an intermediate in the replication of the resistance transfer factor R6K in Escherichia coli

Pulse-labeling of an $\text{Escherichia coli}$ strain harboring the resistance transfer factor R6K results in a transient increase in labeled catenated R6K DNA molecules. After a chase the level of labeled catenated DNA molecules is greatly reduced concomitant with a marked increase in labeling of the supercoiled DNA form of R6K. The data presented support a role for the catenated DNA molecule as an intermediate in the replication of the plasmid R6K.     

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.     

In vivo catenation and decatenation of DNA.

We have noted previously that when circular, but not linear, DNA or chromatin was injected into Xenopus laevis oocytes, much of it went through an intermediate form in which it did not readily enter an agarose gel; after a few hours, it reappeared as monomer DNA that had acquired its full complement of nucleosomes (T. J. Miller and J. E. Mertz, Mol. Cell. Biol. 2:1581-1593, 1982). We determined, using electron microscopy and a variety of biochemical techniques, the structure of this aggregated material. Most of it was oligomeric and multimeric catenanes of the injected sample. In addition, injection of DNA that had been catenated in vitro with DNA gyrase resulted in the conversion of most of it back to monomer circles. These findings demonstrate directly that both catenation and decatenation of DNA occur in vivo under physiological conditions. Whether these reactions play a crucial role in nucleosome formation, as well as in DNA replication and recombination, remains to be determined.     

Identification of a unique domain essential for Escherichia coli DNA topoisomerase III-catalysed decatenation of replication intermediates

A 17-amino-acid residue domain has been identified in Escherichia coli DNA topoisomerase III (Topo III) that is essential for Topo III-mediated resolution of DNA replication intermediates in vitro. Deletion of this domain reduced Topo III-catalysed resolution of DNA replication intermediates and decatenation of multiply linked plasmid DNA dimers by four orders of magnitude, whereas reducing Topo III-catalysed relaxation of negatively supercoiled DNA substrates only 20-fold. The presence of this domain has been detected in multiple plasmid-encoded topoisomerases, raising the possibility that these enzymes may also be decatenases.     

Cohesin's concatenation of sister DNAs maintains their intertwining

The contribution of DNA catenation to sister chromatid cohesion is unclear partly because it has never been observed directly within mitotic chromosomes. Differential sedimentation-velocity and gel electrophoresis reveal that sisters of 26 kb circular minichromosomes are held together by catenation as well as by cohesin. The finding that chemical crosslinking of cohesin's three subunit interfaces entraps sister DNAs of circular but not linear minichromosomes implies that cohesin functions using a topological principle. Importantly, cohesin holds both catenated and uncatenated DNAs together in this manner. In the vicinity of centromeres, catenanes are resolved by spindle forces, but linkages mediated directly by cohesin resist these forces even after complete decatenation. Crucially, persistence of catenation after S phase depends on cohesin. We conclude that by retarding Topo II-driven decatenation, cohesin mediates sister chromatid cohesion by an indirect mechanism as well as one involving entrapment of sister DNAs inside its tripartite ring.     

F plasmid replication and the division cycle of Escherichia coli B/r

A terminal stage in the duplication of many bacterial plasmids involves the transient formation of catenated molecules containing two interlocked monomeric plasmid units. This property of plasmid replication was exploited to examine the relationship between F replication and the division cycle of Escherichia coli B/r cells growing in undisturbed, exponential-phase cultures. Various cultures of F′lac- or FKm^r-containing cells were briefly exposed to [³H]thymidine, and then the transfer of radioactivity into, and out of, a catenated dimer consisting of two closed circular monomers was measured during a chase period. The fraction of plasmid molecules present in this dimer form was determined by separating cellular DNA in alkaline sucrose gradients. In addition, plasmid replication was studied in synchronously growing cultures by measuring both [³H]thymidine incorporation into covalently closed circular DNA and β-galactosidase inducibility. The results suggest that replication of F plasmids can take place throughout the cell division cycle, with the probability of replication increasing toward the end of the cycle. The presence of DNA homologous to the chromosome on the F′lac did not alter the replication pattern of the plasmid during the division cycle.     

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.     

Structure of replicating simian virus 40 minichromosomes. The replication fork, core histone segregation and terminal structures

The structure of replicating simian virus 40 (SV40) minichromosomes was studied by DNA crosslinking with trimethyl-psoralen. The procedure was used both in vitro with extracted SV40 minichromosomes as well as in vivo with SV40-infected cells. Both procedures gave essentially the same results. Mature SV40 minichromosomes are estimated to contain about 27 nucleosomes (error +/- 2), except for those molecules with a nucleosome-free gap, which are interpreted to contain 25 nucleosomes (error +/- 2). In replicative intermediates, nucleosomes are present in the unreplicated parental stem with the replication fork possibly penetrating into the nucleosomal DNA before the histone octamer is removed. Nucleosomes reassociate on the newly replicated DNA branches at distances from the branch point of 225 ( +/- 145) nucleotides on the leading strand and of 285( +/- 120) nucleotides on the lagging strand. In the presence of cycloheximide, daughter duplexes contained unequal numbers of nucleosomes, supporting dispersive and random segregation of parental nucleosomes. These were arranged in clusters with normal nucleosome spacing. We detected a novel type of interlocked dimer comprising two fully replicated molecules connected by a single-stranded DNA bridge. We cannot decide whether these dimers represent hemicatenanes or whether the two circles are joined by a Holliday-type structure. The joining site maps within the replication terminus. We propose that these dimers represent molecules engaged in strand segregation.     

The molecular size and conformation of the chloroplast DNA from higher plants.

Covalently closed circular choloroplast DNA (ctDNA) molecules have been isolated from pea, bean, spinach, lettuce, corn and oat plants by ethidium bromide/cesium choloride density-gradient entrifugation. As much as 30-40% of the total ctDNA could be isolated as closed circular DNA molecules and up to 80% of the total ctDNA was found in the form of circular molecules. The size of pea, spinach, lettuce, corn and oat ctDNA relative to an internal standard (phiX174 replicative form II monomer DNA) was determined by electron microscopy. The ctDNAs showed significant differences in their sizes, and their molecular weights ranged from 85.4 - 10(6) for corn ctDNA to 96.7 - 10(6) for lettuce ctDNA. Each of these ctDNAs contained 3-4% of the circular molecules as circular dimers and 1-2% of the circular molecules as catenated dimes. The molecular complexity of these ctDNAs was studied by renaturation kinetics using T4 DNA as a standard. The molecular weights of the unique sequences of the ctDNAs ranged from 83.7 - 10(6) for oat ctDNA to 93.1 - 10(6) for lettuce ctDNA, which are in excellent agreement with the sizes of the circular ctDNA molecules...