Phenotypes ofdnaA mutants ofEscherichia coli sensitive to phenothiazine derivatives

The activation of DnaA protein by cardiolipin is inhibited by fluphenazinein vitro. We therefore examined the sensitivity of temperature-sensitivednaA mutants ofEscherichia coli to fluphenazine and other phenothiazine derivatives. Among the eightdnaA mutants tested,dnaA5, dnaA46 dnaA602, anddnaA604, mutants with mutations in the putative ATP binding site of DnaA protein, showed higher sensitivities to phenothiazine derivatives than did the wild-type strain. ThednaA508 anddnaA167 mutants, which have mutations in the N-terminal region of DnaA protein, also showed higher sensitivities to phenothiazine derivatives. On the other hand, thednaA204 anddnaA205 mutants, with lesions in the C-terminal region of the DnaA protein, showed the same sensitivity to phenothiazine derivatives as the wild-type strain. Complementation analysis with a plasmid containing the wild-typednaA gene and phage P1-mediated transduction confirmed thatdnaA mutations are responsible for these sensitivity phenotypes.     

Fine structure genetic map and complementation analysis of mutations in the dnaA gene of Escherichia coli

Summary A fine structure genetic map of several mutations in the dnaA gene of Escherichia coli was constructed by the use of recombinant and M13 phages. The dnaA508 mutation was found to be the mutation most proximal to the promoter, while the dnaA203 mutation was found to be the most distal one. The order of mutations established in this analysis was: dnaA508, dnaA167, (dnaA5, dnaA46, dnaA211), dnaA205, dnaA204, dnaA203. The mutations dnaA601, dnaA602, dnaA603, dnaA604 and dnaA606 were found to map very close to each other and close to dnaA205 in the middle third of the dnaA gene. In analysing the dominance relationship all 13 dnaA mutations were found to be recessive to the wild type. Characteristic phenotypes of the dnaA(Ts) mutants, like reversibility of the temperature inactivation of the dnaA protein, cold sensivity of haploid or of merodiploid strains and suppressibility by rpoB mutations, are found to correlate with clusters of mutations within the gene.     

Phenotypes of dnaA mutants of Escherichia coli sensitive to phenothiazine derivatives

The activation of DnaA protein by cardiolipin is inhibited by fluphenazinein vitro. We therefore examined the sensitivity of temperature-sensitivednaA mutants ofEscherichia coli to fluphenazine and other phenothiazine derivatives. Among the eightdnaA mutants tested,dnaA5, dnaA46 dnaA602, anddnaA604, mutants with mutations in the putative ATP binding site of DnaA protein, showed higher sensitivities to phenothiazine derivatives than did the wild-type strain. ThednaA508 anddnaA167 mutants, which have mutations in the N-terminal region of DnaA protein, also showed higher sensitivities to phenothiazine derivatives. On the other hand, thednaA204 anddnaA205 mutants, with lesions in the C-terminal region of the DnaA protein, showed the same sensitivity to phenothiazine derivatives as the wild-type strain. Complementation analysis with a plasmid containing the wild-typednaA gene and phage P1-mediated transduction confirmed thatdnaA mutations are responsible for these sensitivity phenotypes.     

Reinitiation kinetics in eight dnaA(Ts) mutants of Escherichia coli: rifampicin-resistant Initiation of chromosome replication

The kinetics of reinitiation of chromosome replication of eight dnaA(Ts) mutants was investigated in an isogenic set of strains. Five mutants (167, 46, 601, 606 and 5) are classified as reversible, since they can reinitiate at 30 C without protein synthesis, whereas the other three (508, 205, 204) require protein synthesis. In the presence of protein synthesis, reversible mutants initiate one round of replication rapidly after a shift to 30δC, indicating that they contain active or renaturable DnaA protein. The dnaA508 and dnaA204 mutants also reinitiate chromosome replication rapidly, whereas reinitiation is delayed 15–20min in dnaA205. The dnaA508 and dnaA204 mutants might contain active DnaA protein just below the threshold level at 42δC and only require synthesis of small amounts of new DnaA protein before initiation at 30δC, whereas dnaA205 accumulates DnaA protein for some time at 30δC before reaching the initiation threshold. Three of the reversible mutants (5, 601, and 606) exhibited, in addition to the protein synthesis-independent initiation capacity, an RNA synthesis-independent initiation capacity. The thermal stability of these initiation capacities is the same as for mutant DnaA protein, strongly suggesting that mutant DnaA protein is responsible for both.     

Reversibility of DnaA protein activity in the'irreversible'dnaA204 mutant of Escherichia coli

The dnaA204 mutant, one of the so-called irreversible dnaA mutants which cannot reinitiate chromosome replication upon a shift from non-permissive to permissive growth temperature in the absence of protein synthesis, was reinvestigated using flow cytometry and marker frequency analysis. In a temperature downshift experiment and in the presence of protein synthesis the dnaA204 mutant reinitiates chromosome replication very fast. Using a lac promoter-controlled wild type or a dnaA204 mutant gene carried on a plasmid, we have observed instantaneous initiation of replication when synthesis of DnaA protein is induced in the dnaA204 mutant at 42δC. The data indicate that the dnaA204 mutant after a shift to 42δC still contains functional DnaA protein, but that the activity level is below the initiation threshold. Thus, after synthesis of very small amounts of additional DnaA protein, initiation occurs very fast both after a shift to 30δC, and after induction of DnaA protein synthesis at 42 C. A model describing the processing of DnaA protein in mutants and in the wild type Is presented.     

Requirement of DNA Gyrase for the initiation of chromosome replication in Escherichia coli K-12

Summary It has been found that strains carrying mutations in the dnaA gene are unusually sensitive to COU, NAL or NOV, which are known to inhibit DNA gyrase activities. The delay in the initiation of chromosome replication after COU treatment has been observed in cells with chromosomes synchronized by amino acid starvation or by temperature shift-up (dnaA46). The unusual sensitivity of growth to COU of the initiation mutant runs parallel to a higher sensitivity to the drug of the initiation of chromosome replication.The double mutant, dnaA46 cou-110 has been isolated and mutation cou-110 conferring resistance of growth, initiation and elongation of chromosome replication to COU was mapped in the gene coding for the subunit of DNA gyrase. The reduced frequency of appearance of the mutants resistant to COU, NAL or NOV in the initiation mutant suggests that some mutations in genes coding for DNA gyrase subunits cannot coexist with the dnaA46 mutation. The possible mechanisms of the requirement of DNA gyrase for dnaA-dependent initiation of E. coli chromosome are discussed.Abbreviations used COU coumermycin A₁ - NAL nalidixic acid - NOV novobiocin     

Unique organization of the dnaA region from Prochlorococcus marinus CCMP1375, a marine cyanobacterium

In order to study DNA replication control elements in cyanobacteria we cloned and sequenced the dnaA gene from the marine cyanobacterium Prochlorococcus marinus. The dnaA gene is ubiquitous among bacteria and encodes the DNA replication initiation factor DnaA. The deduced amino acid sequence of the P. marinus DnaA protein shows highest similarity to the DnaA protein from the freshwater cyanobacterium Synechocystis sp. PCC6803. Using a solid-phase DNA binding assay we demonstrated that both cyanobacterial DnaA proteins specifically recognize chromosomal origins, oriC, of Escherichia coli and Bacillus subtilis in vitro. The genetic environment of dnaA is not conserved between the two cyanobacteria. Upstream of the P. marinusdnaA gene we identified a gene encoding a putative ATP-binding cassette (ABC) transport protein. The gor gene encoding glutathione reductase lies downstream of dnaA. Comparison of the genetic structure of dnaA regions from 15 representative bacteria shows that the pattern of genes flanking dnaA is not universally conserved among them. Received: 20 July 1997 / Accepted: 7 October 1997     

枯草芽孢杆菌L-脯氨酸合成途径中glnA、proB、proA基因功能探究

【目的】从基因水平探究枯草芽孢杆菌渗透压调节因子L-脯氨酸合成途径中glnA、proB、proA基因的功能,通过分子改造实现对代谢途径的人工扰动。【方法】从枯草芽孢杆菌WB600出发,通过向胞内引入一系列基因敲除或过表达,分别构建了proB和proA基因过表达的重组菌WB601和WB602、glnA基因缺失的重组菌WB603以及在此基础之上过表达proB基因的重组菌WB604。借助菌株胞外和胞内游离脯氨酸积累的表型分析影响途径的关键节点。【结果】在非胁迫条件下,重组菌WB601和WB602胞外脯氨酸含量分别是原始菌的2.21倍和2.82倍,单位细胞胞外脯氨酸得率分别是原始菌的4.09倍和9.80倍,胞内游离脯氨酸含量分别是原始菌的1.91倍和3.34倍;重组菌WB603胞外脯氨酸含量上升至1221.43 mg/L,是原始菌的6.28倍,单位细胞胞外和胞内游离脯氨酸得率分别为原始菌的9.13倍和3.66倍;而重组菌WB604胞外脯氨酸含量最高达1391.65 mg/L,相比菌株WB603,其胞外脯氨酸含量及单位细胞得率分别提高了13.94%和14.10%,且胞内游离脯氨酸含量提高了32.60%。在5%Na Cl胁迫条件下,重组菌WB601和WB602的胞外脯氨酸含量分别是原始菌的1.94倍和1.54倍,单位细胞胞外脯氨酸得率分别是原始菌的2.15倍和2.19倍;重组菌WB603胞外脯氨酸含量及其单位细胞得率分别是原始菌的4.16倍和7.29倍;相同条件下,相比于重组菌WB603,重组菌WB604的胞外脯氨酸含量及其单位细胞得率分别提高了32.61%和5.54%。此外,实验组菌株的胞内游离脯氨酸含量均高于非胁迫时,并达到相对平衡状态。【结论】proB和proA基因的过表达均能显著提升细胞合成脯氨酸的能力,并且能增强细胞的耐盐性;glnA基因的缺失能增强脯氨酸合成途径,提高脯氨酸的积累;两种效应的正向叠加可进一步提升细胞脯氨酸合成能力。     

Integrative suppression of dnaA(Ts) mutations mediated by plasmid F in Escherichia coli is a DnaA-dependent process

Summary The thermosensitivity of dnaA(Ts) mutations can be suppressed by integration of plasmid F (integrative suppression). In the light of the recent finding that F requires DnaA protein for both establishment and maintenance, integrative suppression of 11 dnaA(Ts) mutations by a mini-F, pML31, integrated near oriC was examined. The plating efficiency of integratively suppressed strains was dnaA(Ts) allele-dependent and medium-dependent. The initiation capability of suppressed dnaA(Ts) strains lacking the oriC site and their F^- counterparts was determined at various temperatures between 30°C and 42°C. The degree of integrative suppression measured by the initiation capability varied in a dnaA(Ts) allele-dependent manner. F-directed DNA replication was most affected by the dnaA(Ts) mutations mapping in the middle of the gene whereas oriC-dependent replication was most thermosensitive in strains carrying mutations mapping in the carboxy-terminal half of the gene. The results indicated that the integrative suppression by F plasmid is a DnaA-dependent process and suggested that the requirements for DnaA protein in the oriC-dependent replication and F replication processes are qualitatively different.     

A DNA fragment containing the groE genes can suppress mutations in the Escherichia coli dnaA gene

Summary An 8.2 kb fragment of E. coli chromosomal DNA, when cloned in increased copy number, suppresses the dnaA46 mutation, and an abundant protein of about 68 kd (60 kd when measured by us), encoded by the fragment, is essential for the suppression (Takeda and Hirota 1982). Mapping experiments show that the fragment originates from the 94 min region of the chromosome. It encodes several proteins but only one abundant polypeptide of the correct size, the product of the groEL gene. Suppression by the fragment is allele specific; those mutations which map to the centre of the gene are suppressed. Other initiation mutants including dnaA203, dnaA204, dnaA508, dnaAam, dnaC, dnaP and dnaB252 are not suppressed. Most suppressed strains are cold-sensitive suggesting an interaction between the mutant proteins (or their genes) and the suppressing protein or proteins.     

Role of DnaA protein during replication of plasmid pBR322 in Escherichia coli

Summary The in vivo role of the Escherichia coli protein DnaA in the replication of plasmid pBR322 was investigated, using a plasmid derivative carrying an inducible dnaA ⁺ gene. In LB medium without inducer, the replication of this plasmid, like that of pBR322, was inhibited by heat inactivation of chromosomal DnaA46 protein so that plasmid accumulation ceased 1 to 2 h after the temperature shift. This inhibition did not occur when the plasmid dnaA ⁺ gene was expressed in the presence of the inducer isopropyl-1-thin--d-galactopyranoside (IPTG). Inhibition was also not observed in glycerol minimal medium or in the presence of low concentrations of rifampicin or chloramphenicol. Deletion of the DnaA binding site and the primosome assembly sites (pas, rri) downstream of the replication origin did not affect the plasmid copy number during exponential growth at 30° C, or after inactivation of DnaA by a shift to 42° C in a dnaA46 host, or after oversupply of DnaA, indicating that these sites are not involved in a rate-limiting step for replication in vivo. The accumulation of the replication inhibitor, RNAI, was independent of DnaA activity, ruling out the possibility that DnaA acts as a repressor of RNAI synthesis, as has been suggested in the literature. Changes in the rate of plasmid replication in response to changes in DnaA activity (in LB medium) could be resolved into an early, rom-dependent, and a late, rom-independent component. Rom ^– plasmids show only the late effect. After heat inactivation of DnaC, plasmid replication ceased immediately. These results, together with previously published reports, suggest that DnaA plays no specific role during in vivo replication of ColE1 plasmids and that the gradual cessation of plasmid replication after heat inactivation of DnaA in LB medium results from indirect effects of the inhibition of chromosome replication and the ensuing saturation of promoters with RNA polymerase under nonpermissive growth conditions.     

Characterization of the dnaA, gyrB and other genes in the dnaA region of the Escherichia coli chromosome on specialized transducing phages lambda tna.

Summary Specialized transducing phages tna (tryptophanase) harboring chromosomal DNA and genetic markers from the dnaA region of the Escherichia coli chromosome were isolated. Transductional analysis showed that some of these tnaA transducing phages carry two genes important in DNA replication, namely the dnaA gene (initiation of chromosome replication) and the gyrB gene (subunit B of DNA gyrase), formerly designated cou ^R. The following clockwise order of genetic markers was found: uhp, gyrB, dnaA, rimA, tnaA, bglB.The gene-protein relationship was established by the determination of the gene products encoded on the chromosomal DNA of the different tna. A 54 kD and a 91 kD polypeptide appear to be coded for by the dnaA and gyrB genes, respectively; the 91 kD protein is encoded on a region in which coumermycin sensitivity maps and is with respect to electrophoretic behavior identical to subunit B of DNA gyrase. The 54 kD protein is encoded on the region in which different independently isolated dnaA(Ts) mutations (dnaA5, dnaA46, dnaA167, dnaA203, dnaA204, dnaA205, dnaA211, dnaA508) are located. Additional genes which code for polypeptides with hitherto unknown functions were identified and mapped. The acriflavin sensitivity mutation acrB1 was found to be an allele of the gyrB gene (see Note Added in Proof).     

Studies on the alteration of chromosome copy number and cell division potential in a dnaA mutant of Escherichia coli

Summary The dnaA167 mutant of Escherichia coli, N167, maintains, on the average, two replicating chromosomes per cell at the perimissive growth temperature of 30°C and only one per cell at the higher permissive growth temperature of 38°C. When the growth temperature of this mutant is changed from 30° to 38°C the cells rapidly readjust their chromosome copy number from two to one. I have examined the kinetics of this transition with reference to DNA replication and cell division. My results indicate that this mutant uncouples cell division from chromosome duplication to achieve the appropriate copy number, suggesting that the dnaA gene product may be involved in the coordination between these two cellular events.     

Interaction of the Bacillus subtilis DnaA-like protein with the Escherichia coli DnaA protein.

Plasmids carrying the intact Bacillus subtilis dnaA-like gene and two reciprocal hybrids between the B. subtilis and Escherichia coli dnaA genes were constructed. None of the plasmids could transform wild-type E. coli cells unless the cells contained surplus E. coli DnaA protein (DnaAEc). A dnaA (Ts) strain integratively suppressed by the plasmid R1 origin could be transformed by plasmids carrying either the B. subtilis gene (dnaABs) or a hybrid gene containing the amino terminus of the E. coli gene and the carboxyl terminus of the B. subtilis gene (dnaAEc/Bs). In cells with surplus E. coli DnaA protein, expression of the E. coli dnaA gene was derepressed by the B. subtilis DnaA protein and by the hybrid DnaAEc/Bs protein, whereas it was strongly repressed by the reciprocal hybrid protein DnaABs/Ec. The plasmids carrying the different dnaA genes probably all interfere with initiation of chromosome replication in E. coli by decreasing the E. coli DnaA protein concentration to a limiting level. The DnaABs and the DnaAEc/Bs proteins effect this decrease possibly by forming inactive oligomeric proteins, while the DnaABs/Ec protein may decrease dnaAEc gene expression.     

A temperature-sensitive Escherichia coli mutant defective in DNA replication: dnaA, a new gene adjacent to the dnA, gene

Summary An Escherichia coli mutant defective in replication of the chromosome has been isolated from temperature-sensitive mutants that cannot support colicin E1 plasmid DNA synthesis in the presence of chloramphenicol. Cellular DNA synthesis of the mutant ceases almost immediately after transfer to the nonpermissive temperature. The defect is due to a single mutation, dna-59, which is located close to the sites of dnaA mutations and a cou ^R mutation conferring DNA gyrase with resistance to coumermycin. The dna-59 mutant is not able to support DNA synthesis of phage at the high temperature. The mutant also restricts growth of X174 phage at the high temperature, but permits formation of supercoiled closedcircular duplex replicative intermediates. T7 phage can grow on the mutant even at the high temperature.A specialized transducing phage imm ²¹[tna dnaA]#2 (Miki et al., 1978) supports growth of dna-59, dnaA46 and dna-167 cells at the high temperature. Some of the EDTA-resistant derivatives of the phage have lost part or all of the dnaA gene, but carry gene function complementing the defect of dna-59 cells, as judged by conversion of the above dna strains to wild type cells by phage infection, and by suppression of the loss of viability of dna-59 cells at the high temperature by phage infection. The gene containing the dna-59 mutation site is thus distinct from the dnaA gene. Since the dna-59 mutation does not affect expression of the cou ^r gene of DNA gyrase, which is another known gene involved in DNA synthesis near the dnaA gene, this mutation is probably in a new gene, dnaN. From analysis of the suppression activities of imm ²¹[tna dnaA]#2 phage and its deletion derivatives against dnaN59 cells, it is suggested that the expression of the dnaN gene function is reduced by deletion in the dnaA region.     

Continuous synthesis of the dnaA gene product of Escherichia coli in the cell cycle

Summary The dnaA gene product of Escherichia coli, identified as a weakly basic protein of about 48,000 daltons (Yuasa and Sakakibara 1980), can be separated from other celluar proteins by means of two-dimensional gel electrophoresis. Synthesis of the dnaA protein took place continuously during a cell growth cycle. The newly synthesized dnaA protein persisted stably for one generation. Thermosensitive dnaA protein produced by the dnaA167 mutant was stable at 30° C, but was disintegrated at 42° C. The amount of intact dnaA protein present in the mutant exposed to the high temperature for 60 min was less than a quarter of the amount at the time of the shift. The cells having the reduced amount of intact dnaA protein were capable of initiating a new round of chromosome replication at the low temperature without de novo synthesis of the dnaA protein. The potential of the mutant for initiation of DNA replication decreased with reduction in the amount of the thermoreversible dnaA protein. The mutations dnaA167 and dnaA46 had no significant effect on the syntheses of the dnaA mRNA and the protein product at the low and high temperatures.Abbreviations used SDS sodium dodecyl sulfate - kb kilobase pairs - TCA trichloroacetic acid