Novel Escherichia coli mutant, dnaR, thermosensitive in initiation of chromosome replication.

A newly isolated Escherichia coli mutant thermosensitive in DNA synthesis had an allele named dnaR130, which was located at 26.3 minutes on the genetic map. The mutant was defective in initiation of chromosome replication but not in propagation at a high temperature. This mutant was capable of growing in the absence of the rnh function at the high temperature by means of a dnaA-independent replication mechanism. In the mutant exposed to the high temperature, an oriC plasmid was able to replicate, although at a lower rate than at the low temperature. The plasmid replication at the high temperature depended on the dnaA function essential for the initiation of replication from oriC. The mutant lacking the rnh function persistently maintained the oriC plasmid at the high temperature in a dnaA-dependent manner. Thus, the dnaR function was required for initiation of replication of the bacterial chromosome from oriC but not the oriC plasmid. This result reveals that a dnaR-dependent initiation mechanism that is dispensable for oriC plasmid replication operates in the bacterial chromosome replication.     

Initiation of DNA replication in Bacillus subtilis. IV. The effect of an intercalating dye, ethidium bromide

Summary The effects of an intercalating dye, ethidium bromide (EtBr), on the initiation of chromosome replication in Bacillus subtilis were studied. Spores of a thymine requiring mutant acquired the ability to initiate one round of replication in the absence of RNA and protein synthesis (initiation potential) during germination in a thymine starved medium. When EtBr was added after the initiation potential was fully established, initiation of replication was completely inhibited. This inhibition was reversible, and initiation was resumed when the drug was removed. The recovery of initiation occurred in the absence of protein synthesis but did require RNA synthesis and an active dna gene product.During germination both a DNA-protein complex and a DNA-membrane complex were formed at the replication origin in parallel with the establishment of initiation potential. EtBr destroyed both of these complexes at the concentration which inhibited initiation.The first round of replication of a plasmid DNA, pSL103, during spore germination was also prevented by EtBr. However a higher concentration was required to inhibit plasmid replication. It was found that the plasmid formed two complexes identical to the S- and M-complex of the chromosome origin. Compared to the chromosome complexes the plasmid complexes were less sensitive to EtBr. The loss of sensitivity was equivalent to that for the initiation of the plasmid compared to the chromosome. These results indicate that the target of EtBr is the DNA in the S- and M-complexes whose conformation is essential for the initiation of chromosome and plasmid replication.III of this series is Murakami et al. 1976     

Broad-host-range plasmid replication: an open question

Many factors can influence the ability of plasmids to colonize different hosts, efficient replication probably being the most critical one. Two major strategies seem to facilitate promiscuous plasmid replication: (i) initiation independent of host initiation factors; and (ii) versatile communication between plasmid and host initiation factors. Appropriate communication between a replicon and the different hosts, which becomes crucial at the initation of plasmid replication, plays a major role in plasmid promiscuity. Fused replicons or mechanisms that rescue collapsed replication forks may increase the efficiency of plasmid propagation. However, their contribution to plasmid promiscuous replication remains to be fully evaluated. Several examples of host-specific adaptation of promiscuous plasmids point to an enormous flexibility of these replicons.     

Functional analysis of the leading strand replication origin of plasmid pUB110 in Bacillus subtilis.

Supercoiled plasmid DNA is the substrate for initiation of pUB110 replication, and - by inference - for binding of its initiator protein (RepU) to the plasmid replication origin (oriU) in vivo. No hairpin structure is required for RepU-oriU recognition. RepH (the pC194 replication initiation protein) failed to initiate replication in trans at oriU. The nucleotides that determine the specificity of the replication initiation process are located within oriU but termination is unefficient. Therefore the segment that forms the full recognition signal for termination is probably located 3' of the oriU recognition sequence. Two overlapping domains, one for initiation and one required for termination, compose the leading strand replication origin of plasmid pUB110.     

The Staphylococcus aureus mutation pcrA3 leads to the accumulation of pT181 replication initiation complexes

In Staphylococcus aureus cells carrying the pcrA3 chromosomal mutation, plasmid pT181 and its derivatives were maintained at a reduced copy number. A significant proportion of their DNA migrated during agarose gel electrophoresis as nicked DNA. The results obtained in the characterization of this plasmid DNA species show that it represents replication initiation complexes. Such complexes could not be detected in a wild-type host. The replication initiation complexes present in pcrA3 cells could resume replication after a lag. It was concluded from these results that the pcrA3 host mutation affected a step in plasmid pT181 replication immediately following the formation of the replication initiation complex, and that in pcrA3 this step became rate-limiting for plasmid pT181 replication.     

Recombination-dependent concatemeric plasmid replication.

The replication of covalently closed circular supercoiled (form I) DNA in prokaryotes is generally controlled at the initiation level by a rate-limiting effector. Once initiated, replication proceeds via one of two possible modes (theta or sigma replication) which do not rely on functions involved in DNA repair and general recombination. Recently, a novel plasmid replication mode, leading to the accumulation of linear multigenome-length plasmid concatemers in both gram-positive and gram-negative bacteria, has been described. Unlike form I DNA replication, an intermediate recombination step is most probably involved in the initiation of concatemeric plasmid DNA replication. On the basis of structural and functional studies, we infer that recombination-dependent plasmid replication shares important features with phage late replication modes and, in several aspects, parallels the synthesis of plasmid concatemers in phage-infected cells. The characterization of the concatemeric plasmid replication mode has allowed new insights into the mechanisms of DNA replication and recombination in prokaryotes.     

Initiation of DNA replication in Bacillus subtilis. V. Role of DNA gyrase and superhelical structure in initiation

Summary When spores of a thymine-requiring mutant of Bacillus subtilis were germinated in a medium lacking thymine, an initiation potential (an ability to initiate and complete one round of replication in the presence of thymine and in the absence of protein and RNA synthesis) was formed for both chromosomal and plasmid replication. The effect of two inhibitors of DNA gyrase, novobiocin (Nov) and nalidixic acid (Nal), on the initiation potential formed during germination for chromosomal and plasmid replication was examined.Nov and Nal inhibited formation of the initiation potential completely if the drug was added at the onset of germination. In contrast, initiation of chromosomal and plasmid replication occurred in the presence of DNA gyrase inhibitors when the drug was added after the initiation potential had been fully formed. However, chromosomal replication initiated in the presence of the inhibitors ceased after a fragment of approximately 15 MD (15×10⁶ daltons) had been replicated, and plasmid replication was limited to one round of replication in approximately half of the plasmid molecules present in the spores.Furthermore the initiation potential for both chromosomal and plasmid replication though established was destroyed gradually but steadily by prolonged incubation with Nov in the absence of thymine. In addition, relaxation of the superhelical structure of plasmid DNA during incubation with Nov was observed in vivo. This relaxation was blocked by ethidium bromide, which dissociated the S-complex. On the other hand, incubation with Nal did not reduce the initiation potential nor did it change the superhelicity of the plasmid DNA in vivo. This is consistent with the known effect of gyrase inhibitors on the enzymatic activity of DNA gyrase.These results clearly demonstrate that both the action of DNA gyrase and the superhelical structure of the DNA are essential for the initiation of chromosomal and plasmid replication. The specific chromosome organization essential for initiation and elongation and the role of DNA gyrase are discussed.IV of this series is Yoshikawa et al. 1980     

Identification of putative DnaN-binding motifs in plasmid replication initiation proteins

Recently the plasmid RK2 replication initiation protein, TrfA, has been shown to bind to the beta subunit of DNA Polymerase III (DnaN) via a short pentapeptide with the consensus QL[S/D]LF. A second consensus peptide, the hexapeptide QLxLxL, has also been demonstrated to mediate binding to DnaN. Here we describe the results of a comprehensive survey of replication initiation proteins encoded by bacterial plasmids to identify putative DnaN-binding sites. Both pentapeptide and hexapeptide motifs have been identified in a number of families of replication initiation proteins. The distribution of sites is sporadic and closely related families of proteins may differ in the presence, location, or type of putative DnaN-binding motif. Neither motif has been identified in replication initiation proteins encoded by plasmids that replicate via rolling circles or strand displacement. The results suggest that the recruitment of DnaN to the origin of replication of a replisome by plasmid replication initiation proteins is not generally required for plasmid replication, but that in some cases it may be beneficial for efficiency of replication initiation.     

Host cell variations resulting from F plasmid-controlled replication of the Escherichia coli chromosome.

Cell size and DNA concentration were measured in Escherichia coli K-12 ET64. This strain carries a dnaA (Ts) mutation that has been suppressed by the insertion of the F plasmid into the chromosome. ET64 can grow in a balanced steady state of exponential growth at the restrictive temperature for its dnaA allele (39 degrees C), in which chromosome replication is controlled by the F plasmid, and at the permissive temperature (30 degrees C), in which chromosome replication is controlled by dnaA-oriC. When cells grown at the indicated temperatures were compared, it was observed that at 39 degrees C, the cell mass increased and the amount of cellular DNA decreased slightly; therefore, the DNA concentration was strongly reduced. These changes can neither be explained by the reduction of the generation time (which is only 10-15%) nor from observed changes in the replication time and in the time between DNA synthesis termination and cell division. Variations were mainly due to the increase in cell mass per origin of replication, at initiation, in cells grown at 39 degrees C. Control of chromosome replication by the F plasmid appears to be the reason for the increase in the initiation mass. Other possible causes, such as the modification of growth temperature, the generation time, or both, were discarded. These observations suggest that at one growth rate, the F plasmid replicates at a particular cell mass to F particle number ratio, and that this ratio is higher than the cell mass to oriC ratio at the initiation of chromosome replication. This fact might be significant to coordinate the replication of two different replicons in the same cell.     

Replication of plasmids in gram-negative bacteria.

Replication of plasmid deoxyribonucleic acid (DNA) is dependent on three stages: initiation, elongation, and termination. The first stage, initiation, depends on plasmid-encoded properties such as the replication origin and, in most cases, the replication initiation protein (Rep protein). In recent years the understanding of initiation and regulation of plasmid replication in Escherichia coli has increased considerably, but it is only for the ColE1-type plasmids that significant biochemical data about the initial priming reaction of DNA synthesis exist. Detailed models have been developed for the initiation and regulation of ColE1 replication. For other plasmids, such as pSC101, some hypotheses for priming mechanisms and replication initiation are presented. These hypotheses are based on experimental evidence and speculative comparisons with other systems, e.g., the chromosomal origin of E. coli. In most cases, knowledge concerning plasmid replication is limited to regulation mechanisms. These mechanisms coordinate plasmid replication to the host cell cycle, and they also seem to determine the host range of a plasmid. Most plasmids studied exhibit a narrow host range, limited to E. coli and related bacteria. In contrast, some others, such as the IncP plasmid RK2 and the IncQ plasmid RSF1010, are able to replicate in nearly all gram-negative bacteria. This broad host range may depend on the correct expression of the essential rep genes, which may be mediated by a complex regulatory mechanism (RK2) or by the use of different promoters (RSF1010). Alternatively or additionally, owing to the structure of their origin and/or to different forms of their replication initiation proteins, broad-host-range plasmids may adapt better to the host enzymes that participate in initiation. Furthermore, a broad host range can result when replication initiation is independent of host proteins, as is found in the priming reaction of RSF1010.     

Identification of novel factors involved in or regulating initiation of DNA replication by a genome-wide phenotypic screen in Saccharomyces cerevisiae

DNA replication in eukaryotic cells is tightly regulated to ensure faithful inheritance of the genetic material. While the replicators, replication origins and many replication-initiation proteins in Saccharomyces cerevisiae have been identified and extensively studied, the detailed mechanism that controls the initiation of DNA replication is still not well understood. It is likely that some factors involved in or regulating the initiation of DNA replication have not been discovered. To identify novel DNA replication-initiation proteins and their regulators, we developed a sensitive and comprehensive phenotypic screen by combining several established genetic strategies including plasmid loss assays with plasmids containing a single versus multiple replication origins and colony color sectoring assays. We isolated dozen of mutants in previously known initiation proteins and identified several novel factors, including Ctf1p Ctf3p, Ctf4p, Ctf18p, Adk1p and Cdc60p, whose mutants lose plasmid containing a single replication origin at high rates but lose plasmid carrying multiple replication origins at lower rates. We also show that overexpression of replication initiation proteins causes synthetic dosage lethality or growth defects in ctf1 and ctf18 mutants and that Ctf1p and Ctf18p physically interact with ORC, Cdt1p and MCM proteins. Furthermore, depletion of both Ctf1p and Ctf18p prevents S phase entry, retards S phase progression, and reduces pre-RC formation during the M-to-G1 transition. These data suggest that Ctf1p and Ctf18p together play important roles in regulating the initiation of DNA replication.     

Isolation and characterization of pHW15, a small cryptic plasmid from Rahnella genomospecies 2

A small cryptic plasmid designated pHW15 was isolated from Rahnella genomospecies 2 WMR15 and its complete nucleotide sequence was determined. The plasmid contained 3002 bp with a G+C content of 47.4%. The origin of replication was identified by deletion analysis as a region of about 600 bp. This region had an identity of 70% to the replication origin of the ColE1 plasmid at the nucleotide level. Sequence analysis revealed the typical elements: RNA I, RNA II and their corresponding promoters, a sequence allowing hybridisation of RNA II to the DNA and favouring processing by RNaseH, a single-strand initiation determinant (ssi) that allows initiation of lagging-strand synthesis, and a terH sequence required for termination of lagging-strand synthesis. The plasmid contained three expressed open reading frames, one of which showed homology to a ColE1 plasmid-encoded protein. Furthermore, a multimer resolution site was identified by sequence analysis. Its deletion resulted in formation of plasmid multimers during growth leading to an increased plasmid loss rate.     

Eclipse period during replication of plasmid R1: contributions from structural events and from the copy-number control system

The eclipse period (the time period during which a newly replicated plasmid copy is not available for a new replication) of plasmid R1 in Escherichia coli was determined with the classic Meselson-Stahl density-shift experiment. A mini-plasmid with the wild-type R1 replicon and a mutant with a thermo-inducible runaway-replication phenotype were used in this work. The eclipses of the chromosome and of the wild-type plasmid were 0.6 and 0.2 generation times, respectively, at temperatures ranging from 30 degrees C to 42 degrees C. The mutant plasmid had a similar eclipse at temperatures up to 38 degrees C. At 42 degrees C, the plasmid copy number increased rapidly because of the absence of replication control and replication reached a rate of 350-400 plasmid replications per cell and cell generation. During uncontrolled replication, the eclipse was about 3 min compared with 10 min at controlled replication (the wild-type plasmid at 42 degrees C). Hence, the copy-number control system contributed significantly to the eclipse. The eclipse in the absence of copy-number control (3 min) presumably is caused by structural requirements: the covalently closed circular plasmid DNA has to regain the right degree of superhelicity needed for initiation of replication and it takes time to assemble the initiation factors.     

Functions of fission yeast orp2 in DNA replication and checkpoint control

orp2 is an essential gene of the fission yeast Schizosaccharomyces pombe with 22% identity to budding yeast ORC2. We isolated temperature-sensitive alleles of orp2 using a novel plasmid shuffle based on selection against thymidine kinase. Cells bearing the temperature-sensitive allele orp2-2 fail to complete DNA replication at a restrictive temperature and undergo cell cycle arrest. Cell cycle arrest depends on the checkpoint genes rad1 and rad3. Even when checkpoint functions are wild type, the orp2-2 mutation causes high rates of chromosome and plasmid loss. These phenotypes support the idea that Orp2 is a replication initiation factor. Selective spore germination allowed analysis of orp2 deletion mutants. These experiments showed that in the absence of orp2 function, cells proceed into mitosis despite a lack of DNA replication. This suggests either that the Orp2 protein is a part of the checkpoint machinery or more likely that DNA replication initiation is required to induce the replication checkpoint signal.     

DNA replication initiates at multiple sites on plasmid DNA in Xenopus egg extracts.

Cell-free extracts of Xenopus eggs will replicate plasmid DNA molecules under normal cell cycle control. We have used the neutral/neutral 2-D gel technique to map the sites at which DNA replication initiates in this system. Three different plasmids were studied: one containing the Xenopus rDNA repeat, one containing single copy Xenopus genomic DNA, and another containing the yeast 2 microns replication origin. 2-D gel profiles show that many potential sites of initiation are present on each plasmid, and are randomly situated at the level of resolution of this technique (500-1000 bp). Despite the abundance of sites capable of supporting the initiation of replication, pulse-chase experiments suggest that only a single randomly situated initiation event occurs on each DNA molecule. Once initiation has taken place, conventional replication forks appear to move away from this site at a rate of about 10nt/second, similar to the rate observed in vivo.     

Initiation of DNA replication in ColE1 plasmids containing multiple potential origins of replication.

We have investigated the frequency of replication origin usage in bacterial plasmids containing more than one potential origin. Escherichia coli recA- cells were selectively transformed with pBR322 monomers, dimers, or trimers. Plasmid DNA was isolated and digested with a restriction enzyme that cut the monomer only once, and the replicative intermediates (RIs) were analyzed by neutral/neutral two-dimensional agarose gel electrophoresis. Evidence for initiation outside the linearized plasmid was found only for oligomers. Moreover, in dimers, the intensity of the signal indicative for external initiation was equivalent to that reflecting internal initiation, whereas it was approximately twice as strong in trimers. To determine whether initiation could occur simultaneously at two origins in a single plasmid, we studied the replication of a neodimer in which both units could be unambiguously distinguished. The results showed that although both origins were equally competent to initiate replication, only one was active per plasmid. These observations strongly suggest that in ColE1 plasmids, replication initiates at a single site even when there are several identical potential origins per plasmid. In addition to the conventional two-dimensional gel patterns, novel specific patterns were observed with intensities that varied from one DNA sample to another. These unique patterns were the result of breakage of the RIs at a replication fork. This type of breakage changes both the mass and shape of RIs. When the entire population of RIs is affected, a new population of molecules is formed that may generate a novel pattern in two-dimensional gels.     

Suppression of an Escherichia coli dnaA mutation by the integrated R factor R.100.1: Change of chromosome replication origin in synchronized cultures.

We have followed, by deoxyribonucleic acid-deoxyribonucleic acid hybridization, the order of replication of three chromosomal markers during a synchronous round of replication in three strains of Escherichia coli carrying a dnaAts mutation: one strain in which the F-like R factor R.100.1 was established as a plasmid and two strains in which the dnaA mutation was suppressed by the integration of R.100.1 into the chromosome. In the R+ strain at 30C, replication of the plasmid took place simultaneously with the initiation of chromosome replication at the normal origin. In the integratively suppressed Hfr strains, at 42.5 C, chromosome replication was initiated preferentially from the integrated plasmid; little or no initiation occurred at the normal origin. Similar results were obtained for the one strain tested at 30 C. For both Hfr strains at 42.5 C, the data suggest that at least part of the population replicated bidirectionally. This conclusion had been confirmed using an autoradiographic procedure. Both types of experiment indicate a wide variation in the rate of travel of individual replication forks within the population.