Cell length in a wee dnaA mutant of Escherichia coli.

The cell length of the short siblings of dividing pairs formed in the absence of replication by two strains of Escherichia coli, OV-25-9 [dnaA46 wee(Am)] and OV-25-10 [dnaA46 wee(AM) supF] was measured. In the presence of Wee, the length of these cells increased to those values expected for newborn wild-type cells growing under similar conditions. In its absence, cell length remained at values near the minimum unit length possible for newborn cells. Our results show that both cell elongation and the action of Wee are independent of DNA replication, being compatible with the role proposed for Wee in coordination between cell elongation and division.     

Cardiolipin activation of dnaA protein, the initiation protein of replication in Escherichia coli

ATP binding to dnaA protein is essential for its action in initiating the replication of plasmids that bear the unique origin of the Escherichia coli chromosome (oriC). ADP bound to that site renders dnaA protein inactive for replication. Diphosphatidylglycerol (cardiolipin), a diacidic membrane phospholipid, displaces the bound nucleotide, and in the presence of components that reconstitute replication, fully reactivates the inert ADP form of dnaA protein. The monacidic phosphatidylglycerol is one-tenth as active as cardiolipin, whereas the neutral phosphatidylethanolamine, the principal E. coli phospholipid, is inactive. Fluphenazine, a tranquilizer drug, blocks cardiolipin activation of dnaA protein, in keeping with the inhibitory action of such agents on phospholipid-dependent enzymes. With the use of this drug to terminate cardiolipin action, dependence of the activation on time, elevated temperature, and high levels of ATP was demonstrated. Cardiolipin binding of nucleotide-free dnaA protein prevents binding of ATP and initiation of oriC replication. Removal of a fatty acid from cardiolipin by phospholipase A reverses this inhibitory effect. The strong and specific interaction of cardiolipin, a cell membrane component, with an essential nucleotide-binding site of dnaA protein, the protein essential for the initiation of chromosome replication, may be an important element in regulating the cell cycle.     

Chromosome replication in an Escherichia coli dnaA mutant integratively suppressed by prophage P2.

Escherichia coli CRT4624-P2sig5 is a dnaA mutant in which integration of the prophage P2sig5 has occurred at the attP2II site (min 85). This strain was integratively suppressed, and when cells were shifted to 42 degrees C replication was initiated at a site in or near the P2 prophage. Initially, this replication occurred primarily in the direction that corresponds to the clockwise direction on the genetic map. Replication also occurred in the counterclockwise direction, but the initiation of replication in this direction occurred approximately 40 min later than the initiation of replication in the other direction. Because of this delay, the replication forks that traveled in the clockwise direction were the first to arrive in the region of the replication terminus. These replication forks ceased replication near the aroD locus (min 37), and it is proposed that the replication terminus is between the aroD and rac loci (min 31). A model is proposed for the cycle of chromosome replication in this strain at 42 degrees C.     

Dominance of dnaA+ to dnaA in Escherichia coli.

The dominance of dnaA+ to the dnaA508 mutation was complete and was unaffected by the presence of a copy of the chromosomal replication origin on the episome. These results prove that the dnaA gene of Escherichia coli produces a diffusible product.     

dnaK protein stimulates a mutant form of dnaA protein in Escherichia coli DNA replication

Two proteins have been identified which stimulate a mutant form of dnaA protein in replication of plasmids containing the chromosomal origin, oriC. One of these is dnaK protein by the criteria of (i) absence of stimulatory activity in enzyme fractions from dnaK mutants, (ii) elevated levels of stimulatory activity in fractions from a dnaK protein overproducer, (iii) comigration of the stimulatory protein with authentic dnaK protein by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and (iv) replacement of this stimulatory protein by dnaK protein in stimulation assays. The stimulatory effect of dnaK protein on dnaA46 protein in replication suggests that this interaction, occurring prior to its action in DNA replication, may regulate its activity.     

Suppression of temperature-sensitive chromosome replication of an Escherichia coli dnaX(Ts) mutant by reduction of initiation efficiency

Temperature sensitivity of DNA polymerization and growth of a dnaX(Ts) mutant is suppressible at 39 to 40 degrees C by mutations in the initiator gene, dnaA. These suppressor mutations concomitantly cause initiation inhibition at 20 degrees C and have been designated Cs,Sx to indicate both phenotypic characteristics of cold-sensitive initiation and suppression of dnaX(Ts). One dnaA(Cs,Sx) mutant, A213D, has reduced affinity for ATP, and two mutants, R432L and T435K, have eliminated detectable DnaA box binding in vitro. Two models have explained dnaA(Cs,Sx) suppression of dnaX, which codes for both the tau and gamma subunits of DNA polymerase III. The initiation deficiency model assumes that reducing initiation efficiency allows survival of the dnaX(Ts) mutant at the somewhat intermediate temperature of 39 to 40 degrees C by reducing chromosome content per cell, thus allowing partially active DNA polymerase III to complete replication of enough chromosomes for the organism to survive. The stabilization model is based on the idea that DnaA interacts, directly or indirectly, with polymerization factors during replication. We present five lines of evidence consistent with the initiation deficiency model. First, a dnaA(Cs,Sx) mutation reduced initiation frequency and chromosome content (measured by flow cytometry) and origin/terminus ratios (measured by real-time PCR) in both wild-type and dnaX(Ts) strains growing at 39 and 34 degrees C. These effects were shown to result specifically from the Cs,Sx mutations, because the dnaX(Ts) mutant is not defective in initiation. Second, reduction of the number of origins and chromosome content per cell was common to all three known suppressor mutations. Third, growing the dnaA(Cs,Sx) dnaX(Ts) strain on glycerol-containing medium reduced its chromosome content to one per cell and eliminated suppression at 39 degrees C, as would be expected if the combination of poor carbon source, the Cs,Sx mutation, the Ts mutation, and the 39 degrees C incubation reduced replication to the point that growth (and, therefore, suppression) was not possible. However, suppression was possible on glycerol medium at 38 degrees C. Fourth, the dnaX(Ts) mutation can be suppressed also by introduction of oriC mutations, which reduced initiation efficiency and chromosome number per cell, and the degree of suppression was proportional to the level of initiation defect. Fifth, introducing a dnaA(Cos) allele, which causes overinitiation, into the dnaX(Ts) mutant exacerbated its temperature sensitivity.     

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 chromosome replication after induction of DnaA protein synthesis in a dnaA(null) rhn mutant of Escherichia coli

The kinetics of initiation of chromosome replication after induction of DnaA protein synthesis was studied in a dnaA(null) rnh mutant of Escherichia coli. DnaA protein synthesis was induced to different extents using the wild-type dnaA gene controlled by a lac promoter. Initiation of chromosome replication from oriC, measured as an increase in origin to terminus ratio, took place at different times after addition of an inducer dependent on the DnaA protein synthesis rate. The first initiations always occurred when DnaA protein had accumulated approximately to the average wild-type concentration (24 ng of DnaA protein per ml cells at OD₄₅₀= 1.0) At a low DnaA protein accumulation rate one synchronous round of replication was obtained after 30min of induction. The initiation kinetics obtained when DnaA protein accumulated rapidly was complicated and indicated that other factors might also be involved.     

Allele-specific suppression of dnaA(Ts) mutations by rpoB mutations in Escherichia coli

Summary Extragenic suppressor mutations for dnaA(Ts) mutations mapping in the rpoB gene (-subunit of RNA polymerase) were isolated by selection of spontaneous rifampicin resistant mutants and screening for temperature resistance. Six rpoB mutations were analysed for suppression of 12 different dnaA(Ts) mutations. The analysis showed that all dnaA(Ts) mutations could be suppressed by some rpoB mutation. All six rpoB mutations showed allele specificity when tested for suppression of 12 dnaA (Ts) mutant strains. The allele specificity was found to correlate with the map position of the dnaA (Ts) alleles.     

Trans-dominance of dnaA mutants in Escherichia coli.

Summary Temperature sensitivity of growth and DNA synthesis was tested in merogenotes heterozygous for thednaA allele. All combinations tested (FdnaA⁺/dnaA5, FdnaA⁺/dnaA46, FdnaA⁺/dnaA204, FdnaA5/dnaA⁺, FdnaA204/dnaA⁺) were temperature sensitive. The mutantdnaA allele is thus trans-dominant to the wild type allele.     

Escherichia coli dnaA initiation function is required for replication of plasmids derived from coliphage lambda

The dnaA gene function, indispensable for the initiation of Escherichia coli replication from oriC is not essential for the growth of phage lambda. The in-vitro replication of plasmids derived from phage lambda does not seem to require DnaA protein either. However, we present evidence that in vivo the normal replication of lambda plasmids is dnaA-dependent. After inactivating the dnaA gene function, half of the plasmid molecules may enter a single round of replication. Rifampicin sensitivity of this abortive, as well as normal, replication indicates involvement of RNA polymerase. The rifampicin resistance of the normal replication of lambda plasmids in E. coli carrying the dnaAts46 or dnaAts5, but not the dnaAts204 allele at 30 degrees C implies the interaction of DnaA protein and RNA polymerase in this process. We propose that DnaA protein co-operates with RNA polymerase in the initiation of replication at ori lambda. The dispensability of DnaA in the growth of phage lambda and in lambda plasmid replication in vitro is discussed.     

Replication of ColE1 plasmid deoxyribonucleic acid in a thermosensitive dnaA mutant of Escherichia coli.

The replication of ColE1 deoxyribonucleic acid (DNA) took place at the restrictive temperature in a dnaA mutant, dnaA167(Ts). It proceeded at a constant rate at 42 degrees C for at least 3 h. The replication was insensitive to rifampin, which blocked replication at the permissive temperature or in the presence of chloramphenicol, even at the restrictive temperature. A linear DNA strand of ColE1 longer than unit genome size was synthesized. The structure of the replicating molecules observed by electron microscopy was mostly sigma shaped, composed of a circle of a unit genome length with a double-stranded tail. These observations suggest that the replication of ColE1 DNA proceeds via a rolling-circle type of structure in the absence of dnaA function.     

Discontinuity in DNA replication during expression of accumulated initiation potential in dnaA mutants of Escherichia coli.

Potential for initiation of chromosome replication present in temperature-sensitive, initiation-defective dnaA5 mutants of Escherichia coli B/r incubated at nonpermissive temperature was expressed by shifting to a more permissive temperature (25 degrees C). Upon expression of initiation potential, the rate of [3H]thymidine incorporation varied in a bimodal fashion, i.e., there was an initial burst of incorporation, which lasted 10 to 20 min, then a sudden decrease in incorporation, and finally a second rapid increase in incorporation. Analyses of this incorporation pattern indicated that a round of replication initiated upon expression of initiation potential, but DNA polymerization stopped after replication of 5 to 10% of the chromosome. This round of replication appeared to resume about 30 min later coincident with initiation of a second round of replication. The second initiation was unusually sensitive to low concentrations of novobiocin (ca. 1 microgram/ml) when this inhibitor was added in the presence of chloramphenicol. In the absence of chloramphenicol, novobiocin at this concentration had no detectable effect on DNA replication. It is suggested that cis-acting inhibition, attributable to an attempted second initiation immediately after the first, caused the first round to stall until both it and the second round could resume simultaneously. This DNA replication inhibition, probably caused by overinitiation, could be a consequence of restraints on replication in the vicinity of oriC, possibly topological in nature, which limit the minimum interinitiation interval in E. coli.     

Defective dissociation of a "slow" RecA mutant protein imparts an Escherichia coli growth defect

The RecA and some related proteins possess a simple motif, called (KR)X(KR), that (in RecA) consists of two lysine residues at positions 248 and 250 at the subunit-subunit interface. This study and previous work implicate this RecA motif in the following: (a) catalyzing ATP hydrolysis in trans,(b) coordinating the ATP hydrolytic cycles of adjacent subunits, (c) governing the rate of ATP hydrolysis, and (d) coupling the ATP hydrolysis to work (in this case DNA strand exchange). The conservative K250R mutation leaves RecA nucleoprotein filament formation largely intact. However, ATP hydrolysis is slowed to less than 15% of the wild-type rate. DNA strand exchange is also slowed commensurate with the rate of ATP hydrolysis. The results reinforce the idea of a tight coupling between ATP hydrolysis and DNA strand exchange. When a plasmid-borne RecA K250R protein is expressed in a cell otherwise lacking RecA protein, the growth of the cells is severely curtailed. The slow growth defect is alleviated in cells lacking RecFOR function, suggesting that the defect reflects loading of RecA at stalled replication forks. Suppressors occur as recA gene alterations, and their properties indicate that limited dissociation by RecA K250R confers the slow growth phenotype. Overall, the results suggest that recombinational DNA repair is a common occurrence in cells. RecA protein plays a sufficiently intimate role in the bacterial cell cycle that its properties can limit the growth rate of a bacterial culture.     

Cooperation of the prs and dnaA gene products for initiation of chromosome replication in Escherichia coli.

A new Escherichia coli mutant allele, named dnaR, that causes thermosensitive initiation of chromosome replication has been identified to be an allele of the prs gene, the gene for phosphoribosylpyrophosphate synthetase (Y. Sakakibara, J. Mol. Biol. 226:979-987, 1992; Y. Sakakibara, J. Mol. Biol. 226:989-996, 1992). The dnaR mutant became temperature resistant by acquisition of a mutation in the dnaA gene that did not affect the intrinsic activity for the initiation of replication. The suppressor mutant was capable of initiating replication from oriC at a high temperature restrictive for the dnaR single mutant. The thermoresistant DNA synthesis was inhibited by the presence of the wild-type dnaA allele at a high but not a low copy number. The synthesis was also inhibited by an elevated dose of a mutant dnaR allele retaining dnaR activity. Therefore, thermoresistant DNA synthesis in the suppressor mutant was dependent on both the dnaA and the dnaR functions. On the basis of these results, I conclude that the initiation of chromosome replication requires cooperation of the prs and dnaA products.