Bacteriophage Mu DNA replication in vitro

An in vitro system for bacteriophage Mu DNA replication using lysates on cellophane discs is described. Mu replication was monitored by DNA hybridization. Using a thermoinducible Mu lysogen, 30-50% of all DNA synthesis in vitro was Mu-specific. Mu DNA synthesis is semidiscontinuous. In the presence of the DNA ligase inhibitor NMN, about one-half of the DNA was in Okazaki pieces and one-half in large DNA. The Mu Okazaki pieces hybridized mainly to the Mu light strand; the large DNA hybridized mainly to the Mu heavy strand. Okazaki pieces isolated from uninfected cells also hybridized to 2000-3000 bases of host DNA present in Mu-separated strands. However, the host Okazaki pieces hybridize to both Mu strands symmetrically. Most, if not all, host sequences were represented in mature Mu viral DNA. The in vitro data are most consistent with models in which Mu sequences, oriented randomly in both directions in the host chromosome, have recruited a bacterial replisome which traverses the Mu genome from left to right.     

In vitro constructed plasmids containing both ends of bacteriophage Mu DNA express phage functions

Summary The construction of a plasmid carrying the right end PstI·B fragment of bacteriophage Mu DNA and of plasmids containing in addition the left end EcoRI·C fragment of Mu DNA into the vector pBR322 is described. Inversion of the G segment still occurs in all these plasmids. By marker rescue and complementation experiments the right PstI cleavage site was located to the left of gene Q. The composite plasmids inheriting also the left end EcoRI fragment of Mu DNA express both the immunity and killing functions of Mu and direct the in vitro synthesis of presumably Mu-specific polypeptides. These results demonstrate that Mu-specific functions can be analyzed from cloned fragments.     

The cis-acting DNA sequences required in vivo for bacteriophage Mu helper-mediated transposition and packaging

The 37,000 bp double-stranded DNA genome of bacteriophage Mu behaves as a plaque-forming transposable element of Escherichia coli. We have defined the cis-acting DNA sequences required in vivo for transposition and packaging of the viral genome by monitoring the transposition and maturation of Mu DNA-containing pSC101 and pBR322 plasmids with an induced helper Mu prophage to provide the trans-acting functions. We found that nucleotides 1 to 54 of the Mu left end define an essential domain for transposition, and that sequences between nucleotides 126 and 203, and between 203 and 1,699, define two auxiliary domains that stimulate transposition in vivo. At the right extremity, the essential sequences for transposition require not more than the first 62 base pairs (bp), although the presence of sequences between 63 and 117 bp from the right end increases the transposition frequency about 15-fold in our system. Finally, we have delineated the pac recognition site for DNA maturation to nucleotides 32 to 54 of the Mu left end which reside inside of the first transposase binding site (L1) located between nucleotides 1–30. Thus, the transposase binding site and packaging domains of bacteriophage Mu DNA can be separated into two well-defined regions which do not appear to overlap.Abbreviations attL attachment site left - attR attachment site right - bp base pairs - Kb kilobase pair - nt nucleotide - Pu Purine - Py pyrimidine - Tn transposable element State University of New York, Downstate Medical Center, Brooklyn, NY 11204 USA     

Identification of an origin of bidirectional DNA replication in mammalian chromosomes

Mechanistically, an origin of bidirectional DNA replication (OBR) can be defined by the transition from discontinuous to continuous DNA synthesis that must occur on each template strand at the site where replication forks originate. This results from synthesis of Okazaki fragments predominantly on the retrograde arms of forks. We have identified these transitions at a specific site within a 0.45 kb sequence approximately 17 kb downstream from the 3' end of the dihydrofolate reductase gene in Chinese hamster ovary chromosomes. At least 80% of the replication forks in a 27 kb region emanated from this OBR. Thus, initiation of DNA replication in mammalian chromosomes uses the same replication fork mechanism previously described in a variety of prokaryotic and eukaryotic genomes, suggesting that mammalian chromosomes also utilize specific cis-acting sequences as origins of DNA replication.     

Duplex opening by primosome protein PriA for replisome assembly on a recombination intermediate.

PriA and other primosome assembly proteins of Escherichia coli recruit the major replicative helicase DnaB for replisome assembly during bacteriophage Mu transposition and replication. MuA transposase catalyzes the transfer of Mu ends to target DNA, forming a potential replication fork that provides the assembly site for the replisome. However, this fork lacks the single-stranded DNA needed to load DnaB. Although no pre-existing primosome assembly sites that bind PriA were found within the Mu end sequences, PriA was able to bind to the forked DNA structure created by MuA. The helicase activity of PriA could then open the duplex to create the DnaB binding site. In a tightly coupled reaction on synthetic forked substrates, PriA promoted both the unwinding of the lagging strand arm and preprimosome assembly to load DnaB onto the lagging strand template. PriA apparently translocated 3' to 5' along the lagging strand template until sufficient single-stranded DNA was exposed for binding of DnaB, which then translocated 5' to 3' in the opposite direction. Mutant PriA lacking helicase activity was unable to promote this process, and loss of PriA helicase impaired Mu DNA replication in vivo and in vitro. This suggests that the opening of the duplex by PriA helicase is a critical step in the initiation of Mu DNA replication. Concerted helicase and primosome assembly functions would allow PriA to act as initiator on recombination intermediates and stalled replication forks. As part of the replisome, PriA may act as a mobile initiator that minimizes interruptions in chromosomal replication.     

Characterization of vaccinia virus DNA replication mutants with lesions in the D5 gene

The vaccinia virus D5 gene encodes a 90 kDa early protein that is essential for viral DNA replication. In this report we map and explore the phenotypes of the temperature sensitive mutants bearing lesions in this gene:ts17,ts24,ts69, (WR strain) andts6389 (IHD strain). Viral DNA synthesis was virtually undetectable during non-permissive infections performed withts17, and incorporation of³H-thymidine ceased rapidly when cultures were shifted to the non-permissive temperature in the midst of replication. The D5 protein may therefore be involved in DNA synthesis at the replication fork. The lesions of the four mutants were localized within the D5orf by marker rescue, and the single nucleotide changes responsible for thets phenotype of the three WR mutants were identified. Unexpectedly, the three alleles with N-terminal mutations were impaired in marker rescue when homologous recombination with small (<2 kb), intragenic DNA fragments at 39.5°C was required. This deficiency was not due to degradation of transfected DNA under non-permissive conditions. Efficient marker rescue could be restored by incubation at the permissive temperature for a brief period after transfection, suggesting a requirement for functional D5 in genome/plasmid recombination. Marker rescue under non-permissive conditions could alternatively be restored by co-transfection of unlinked but contiguous DNA sequences.     

Synchronization of bacteriophage Mu DNA replicative transposition: analysis of the first round after induction.

The lytic cycle of bacteriophage Mu includes a large number of coupled DNA replication and integration events, each of which is equivalent in several respects to the process of transposition of genetic elements. To aid us in studying the process of Mu DNA replicative transposition, we developed a technique for synchronizing the first round of replication following induction of a lysogen. Synchronization was achieved by inducing a lysogen in the absence of DNA replication for a time sufficient to develop the potential for Mu DNA replication in all cells in the population; upon release of the inhibition of replication, a synchronized round of Mu DNA replication was observed. Development of the potential for Mu DNA replication in the entire population took approximately 12 min. Protein synthesis was required for development of the potential, but the requirement for protein synthesis was satisfied by approximately 9 min suggesting that other, as yet unspecified, reactions occupied the last 3 min. Replication proceeded predominantly from the left end of the prophage, though a significant amount of initiation from the right end was observed. The usefulness of the technique for studying the mechanism of replicative transposition and the end products of a single round of replication are discussed.     

Replication of mammalian DNA in vitro. Evidence for initiation from fiber autoradiography

We have used fiber autoradiography to examine the DNA product made in vitro in a lysed cell system. CHO cells were treated with 0.01% Brij-58 and the lysates were incubated at 30 degrees C in a complete reaction mixture for in vitro DNA synthesis with [3H]thymidine triphosphate ([3H]TTP) as the radioactive tracer. Fiber autoradiograms prepared from the DNA showed that it was synthesized on tandemly arranged replication units that were of average size of 20 micrometers, very similar to the size of units found in vivo. The rate of replication fork movement was 25--50% of the in vivo rate. More than 80% of forks stopped functioning by 15 min, and 95% stopped by 60 min. This suggests that synthesis is halted by premature terminations. Evidence for new initiations was provided by replication units with labeled origins in DNA synthesized in an in vitro reaction in which radioactivity was omitted for the first 10 min of incubation. This, plus the observations that the distance between initiation points (replication unit size) is not increased and that premature termination accounts largely for the cessation of synthesis, suggest that significant initiation takes place in this in vitro replication system.     

Dam methylated and hemimethylatedoriC plasmids are replicated symmetrically; a novel and general test of replication symmetry

Summary Deoxyadenosine methylation (dam) of the numerous GATC sequences present in theEscherichia coli origin of chromosomal replication (oriC) has been shown to be important both in vivo and in vitro for efficient initiation of DNA synthesis. Recent in vivo data suggest that initiation is only inefficient when these sequences are hemimethylated. This raises the interesting possibility that initiation may be inefficient because it only takes place on one strand of the template, i.e., replication is asymmetric on hemimethylated DNA. We tested this possibility by a novel and rapid approach which relies on the specificities of the restriction endonucleasesMboI,MboII andDpnI. Although we show that replication takes place equally well on both strands of methylated and hemimethylatedoriC DNA templates, the method should be applicable to the analysis of replication symmetry on most DNA templates which contain methylated deoxyadenosine GATC sequences as part ofMboII restriction sites.     

Alteration of the rate of cell division independent of the rate of DNA synthesis in a mutant of Salmonella typhimurium

Summary Salmonella typhimurium strain IIG has a temperature—sensitive DNA synthesis initiation apparatus and completes rounds of DNA replication when shifted to 38°. At this temperature there is a period of apparently normal division followed by a second phase in which DNA-less cells are produced. The rate of division in this second phase can be markedly increased if a culture growing in MM is shifted to nutrient broth at the time of the temperature shift. The extra divisions induced by the nutritional shift are not due to extra replication forks being introduced by this process nor to the rapid growth of ts ⁺ revertants. It is concluded that in this strain at 38°, the rate of division can be increased without altering the rate of DNA synthesis. The extra divisions induced by the shift-up do not take place for about 90 min. The possible occurrence of such a period between the triggering of division and the division event in normal cells is discussed.     

Bacteriophage Mu: a transposing replicon

Mu DNA replication has been carried out in vitro on cellophane discs in the presence of dBUTP. If the DNA is sheared to 80 kb pieces, the Mu replicas band anomalously in CsCl gradients between hybrid and light DNA density positions. The intermediate density DNA comprises semiconservatively replicated Mu sequences, flanked by unreplicated light DNA. This and previous data are consistent with replication occurring within Mu boundaries. Both the synthesis of Mu sequences and the intermediate density DNA are abolished by protein synthesis inhibition in vivo just prior to lysis on cellophane discs. These observations indicate that at least some steps in bona fide Mu transposition-replication are being observed in vitro.     

Resistance of Adenoviral DNA Replication to Aphidicolin Is Dependent on the 72-Kilodalton DNA-Binding Protein

Aphidicolin is a highly specific inhibitor of DNA polymerase α and has been most useful for assessing the role of this enzyme in various replication processes (J. A. Huberman, Cell 23:647-648, 1981). Both nuclear DNA replication and simian virus 40 DNA replication are highly sensitive to this drug (Krokan et al., Biochemistry 18:4431-4443, 1979), whereas mitochondrial DNA synthesis is completely insensitive (Zimmerman et al., J. Biol. Chem. 255:11847-11852, 1980). Adenovirus DNA replication is sensitive to aphidicolin, but only at much higher concentrations. These patterns of sensitivity are seen both in vivo and in vitro (Krokan et al., Biochemistry 18:4431-4443, 1979). A temperature-sensitive mutant of adenovirus type 5 known as H5ts125 is able to complete but not initiate new rounds of replication at nonpermissive temperatures (P. C. van der Vliet and J. S. Sussenbach, Virology 67:415-426, 1975). When cells infected with H5ts125 were shifted from permissive (33°C) to nonpermissive (41°C) conditions, the residual DNA synthesis (elongation) showed a striking increase in sensitivity to aphidicolin. The temperature-sensitive mutation of H5ts125 is in the gene for the 72-kilodalton single-stranded DNA-binding protein. This demonstrated that the increased resistance to aphidicolin shown by adenovirus DNA replication was dependent on that protein. It also supports an elongation role for both DNA polymerase α and the 72-kilodalton single-stranded DNA-binding protein in adenovirus DNA replication. Further support for an elongation role of DNA polymerase α came from experiments with permissive temperature conditions and inhibiting levels of aphidicolin in which it was shown that newly initiated strands failed to elongate to completion.     

The phiX174-type primosome promotes replisome assembly at the site of recombination in bacteriophage Mu transposition.

Initiation of Escherichia coli DNA synthesis primed by homologous recombination is believed to require the phiX174-type primosome, a mobile priming apparatus assembled without the initiator protein DnaA. We show that this primosome plays an essential role in bacteriophage Mu DNA replication by transposition. Upon promoting transfer of Mu ends to target DNA, the Mu transpososome undergoes transition to a pre-replisome that permits initiation of DNA synthesis only in the presence of primosome assembly proteins PriA, DnaT, DnaB and DnaC. These assembly proteins promote the engagement of primase and DNA polymerase III holoenzyme, initiating semi-discontinuous replication preferentially at the Mu left end. The results indicate that these proteins play a crucial role in promoting replisome assembly on a recombination intermediate.     

A mutant ofLactobacillus acidophilus with temperature-sensitive regulation of DNA synthesis

Among other temperature-sensitive mutants ofLactobacillus acidophilus the mutant “ts 9” with temperature-sensitive initiation of DNA synthesis was isolated. In this mutant, the course of DNA synthesis under non-permissive conditions proceeds in two phases. During the first 90–120 min, a slight increase (20–50%) of DNA content takes place. Then during further incubation at 40°C, the capacity for initiation of further DNA synthesis increases and a second round of DNA synthesis starts after 3–4h of incubation. The initiation of DNA synthesis is prevented by chloramphenicol and the preceding lag is temperature-dependent. It is concluded that an accumulation of an initiation factor is required for the onset of a new cycle of DNA synthesis and that in thets 9 mutant this accumulation is inhibited at non-permissive temperature.     

Differential chromosomal and mitochondrial DNA synthesis in temperature-sensitive mutants ofUstilago maydis

Summary The amount and type of residual DNA synthesis was determined in eight temperature-sensitive mutants of the smut fungusUstilago maydis after incubation at the restrictive temperature (32° C) for eight hours. Mutantsts-220,ts-207,ts-432 andts-346 were found to have an overall reduction in the synthesis of both nuclear and mitochondrial DNA in comparison to the wild-type. In mutantsts-20,tsd 1-1,ts-84 andpol 1-1 nuclear DNA synthesis was depressed relative to mitochondrial synthesis. The DNA-polymerase mutantpol 1-1 had persistent nuclear synthesis at about 50% of the rate of synthesis of mitochondrial DNA and similar behavior was observed in a diploid homozygous strain. Mutantts-84 had an initial burst of DNA synthesis which was reduced for nuclear but not mitochondrial synthesis after three hours preincubation at 32°C.tsd 1-1 andts-20 had nuclear residual synthesis amounting to about 25% of the relative rate of mitochondrial synthesis with correlates to increasing UV sensitivity of these strains on incubation at 32° C. Apol 1-1ts-84 double mutant had an additive loss of nuclear DNA synthesis which indicates that the steps of replication involved may be sequential.     

Bacillus subtilis RarA acts at the interplay between replication and repair-by-recombination

Bacterial RarA is thought to play crucial roles in the cellular response to blocked replication forks. We show that lack of Bacillus subtilis RarA renders cells very sensitive to H₂O₂, but not to methyl methane sulfonate or 4-nitroquinoline-1-oxide. RarA is epistatic to RecA in response to DNA damage. Inactivation of rarA partially suppressed the DNA repair defect of mutants lacking translesion synthesis polymerases. RarA may contribute to error-prone DNA repair as judged by the reduced frequency of rifampicin-resistant mutants in ΔrarA and in ΔpolY1 ΔrarA cells. The absence of RarA strongly reduced the viability of dnaD23ts and dnaB37ts cells upon partial thermal inactivation, suggesting that ΔrarA cells are deficient in replication fork assembly. A ΔrarA mutation also partially reduced the viability of dnaC30ts and dnaX51ts cells and slightly improved the viability of dnaG40ts cells at semi-permissive temperature. These results suggest that RarA links re-initiation of DNA replication with repair-by-recombination by controlling the access of the replication machinery to a collapsed replication fork.     

Yeast and mammalian replication intermediates migrate similarly in two-dimensional gels

In the budding yeast, Saccharomyces cerevisiae, DNA replication initiates at specific, discrete chromosomal locations. At each initiation site, a single small replication bubble is generated, which subsequently expands at Y-like replication forks. We wanted to know whether other eukaryotic organisms utilize similar initiation mechanisms. For this purpose, replication intermediates (RIs) from three different organisms (Schizosaccharomyces pombe, Chinese hamster and human) were mixed individually with RIs from S. cerevisiae and then subjected to two-dimensional (2D) gel electrophoresis under conditions known to resolve molecules having different structures. All of the RIs detected by the hybridization probes we used for each organism migrated nearly identically to specific RIs of similar size from S. cerevisiae, implying that the detected RIs from all the studied organisms have very similar structures and may therefore employ the same basic initiation mechanism.     

Kinetics of Mu DNA synthesis

Summary Mu specific DNA synthesis starts at 10 min after infection. All essential amber mutants of Mu were tested for the ability to replicate in a non permissive host. Except for the amber mutants A and B, which were already known to be blocked in Mu DNA synthesis (Wijffelman et al., 1974), all the other mutants showed normal Mu DNA replication.Using mitomycin C-treated cells Mu DNA synthesis was found to start at about 20 min after induction. However using the much more sensitive method of DNA-RNA hybridization, it was found that the DNA synthesis starts already at 10 min after induction, and that at 20 min after induction about 7 copies of the Mu DNA are present per cell.