Identification of new cell division genes in Escherichia coli by using extragenic suppressors.

To facilitate the analysis of the cell division control apparatus in Escherichia coli, we studied extragenic suppressor mutations of a previously characterized temperature-sensitive division mutation, ftsM1. Cells of strain GD40 which harbor this mutation were spread on agar plates and incubated at 42 degrees C, and the surviving cells were analyzed for the presence of a suppressor mutation. One group of suppressed mutants had acquired a new mutation which, by conjugation, was found to be located in the 30- to 40-min region of the E. coli genetic map. The other group comprised revertants carrying a suppressor which appeared to map between thr and leu. This suppressor gene, called sftA, was cloned with a mini-Mu-derived in vivo cloning system by selection for suppression of temperature sensitivity in GD40 cells. Subsequent subcloning of a fragment of the chromosomal DNA from the mini-Mu plasmid into pBR325 resulted in the delineation of the suppressor gene on a 1.8-kilobase XhoI-PvuI fragment. A strain, CV514, which does not express the temperature sensitivity phenotype of the ftsM1 mutation, was found to harbor a natural suppressor of this mutation. UV sensitivity, another known phenotype of the ftsM1 mutation, was also corrected by the presence of the sftA suppressor in the cell. Thus, the characterization of extragenic suppressors may allow the identification of new genes involved in the control of cell division.     

Cloning and characterization of dnaA(Cs), a mutation which leads to overinitiation of DNA replication in Escherichia coli K-12.

The product of the dnaA gene is essential for the initiation of chromosomal DNA replication in Escherichia coli K-12. A cold-sensitive mutation, dnaA(Cs), was originally isolated as a putative intragenic suppressor of the temperature sensitivity of a dnaA46 mutant (G. Kellenberger-Gujer, A. J. Podhajska, and L. Caro, Mol. Gen. Genet. 162:9-16, 1978). The cold sensitivity of the dnaA(Cs) mutant was attributed to a loss of replication control resulting in overinitiation of DNA replication. We cloned and sequenced the dnaA gene from the dnaA(Cs) mutant and showed that it contains three point mutations in addition to the original dnaA46(Ts) mutation. The dnaA(Cs) mutation was dominant to the wild-type allele. Overproduction of the DnaA(Cs) protein blocked cell growth. In contrast, overproduction of wild-type DnaA protein reduced the growth rate of cells but did not stop cell growth. Thus, the effect of elevated levels of the DnaA(Cs) protein was quite different from that of the wild-type protein under the same conditions.     

dfp Gene of Escherichia coli K-12, a locus affecting DNA synthesis, codes for a flavoprotein.

The cloned dfp gene complements dna-707 (now designated dfp-707), a temperature-sensitive conditionally lethal mutation that results in a slow cessation of DNA synthesis while protein synthesis is maintained. In vitro and in vivo experiments failed to demonstrate a specific defect in the initiation of DNA replication, and turn-off of DNA synthesis at high temperature was slower than that of a typical initiation (dnaA) mutant. The gene was localized, and its product was identified through the construction and analysis of deletion and insertion mutants of dfp-containing plasmids. dfp is located between the rpmB and dut genes at 81 min on the linkage map of Escherichia coli K-12. It is transcribed clockwise, independently of dut. The ability of a plasmid to complement a chromosomal dfp-707 mutation was correlated with its ability to produce a 45-kilodalton polypeptide. The purified protein contained 1 mol of flavin mononucleotide per mol of polypeptide.     

Evidence for the involvement of the 16kD gene promoter in initiation of chromosomal replication of Escherichia coli strains carrying a B/r-derived replication origin.

Initiation of chromosomal DNA replication of several Escherichia coli dnaA (Ts) strains is diminished in cell harbouring pBR322 hybrid plasmids carrying both oriC and the adjacent 16kD gene promoter of E. coli K12. This perturbance, resulting in very slow growth, is caused both by the dnaA allele and the E. coli B/r-derived region of the replication origin of these strains. Cloning and DNA sequence analysis of the E. coli B/r replication origin revealed several base differences as compared to the E. coli K12 sequence. The replication origin of temperature sensitive fast growing mutants, originating from a homologous exchange between chromosomal and plasmid DNA sequences were also cloned. Sequence data showed that a single base change within the promoter of the 16kD gene of these dnaA (Ts) strains is able to suppress the inhibition of chromosomal DNA replication by the mentioned pBR322 hybrid plasmids. Our results strongly indicate a role of the 16kD gene promoter in control of initiation of chromosomal DNA replication.     

Isolation of a dnaA mutant of Bacillus subtilis defective in initiation of replication: amount of DnaA protein determines cells'' initiation potential.

The dnaA gene is essential for initiation of chromosomal replication in Escherichia coli. A gene homologous with the E. coli dnaA was found in the replication origin region of the Bacillus subtilis chromosome. We have now isolated a temperature sensitive mutant of the B. subtilis dnaA by in vitro mutagenesis of the cloned gene. At a nonpermissive temperature, 49 degrees C, DNA replication stops completely after 60% increase in a rich medium, while cell mass continues to increase exponentially at 2.5 times the rate at 30 degrees C. A ratio of gene frequency between purA (origin marker) and metB (terminus marker) changes gradually from 2.7 at 30 degrees C to 1.0 in 45 min at 49 degrees C, indicating completion of the ongoing replication cycle. Upon the temperature shift down to 30 degrees C after the incubation at 49 degrees C for 60 min, DNA replication resumes without delay, and the purA/metB ratio increases rapidly to 6, i.e. consecutive initiation of more than two rounds of replication. Addition of chloramphenicol at the time of the temperature shift down did not inhibit the increase in the purA/metB ratio, while rifampicin inhibited the re-initiation completely. The mutation is a single base change from C to T in the dnaA gene resulting in an amino acid substitution from Ser to Phe in the DnaA protein. The mutation was responsible for both temperature sensitive growth and the defect in initiation of chromosomal replication. We observed a remarkable correlation between the amount of DnaA protein and the amount of initiation potential accumulated during incubation at the non-permissive temperature.     

Mycobacterium smegmatis dnaA region and autonomous replication activity.

Two key elements that are thought to be required for replication initiation in eubacteria are the DnaA protein, a trans-acting factor, and the replication origin, a cis-acting element. As a first step in studying the replication initiation process in mycobacteria, we have isolated a 4-kb chromosomal DNA fragment from Mycobacterium smegmatis that contains the dnaA gene. Nucleotide sequence analysis of this region revealed homologies with the rpmH gene, which codes for the ribosomal protein L34, the dnaA gene, which codes for the replication initiator protein DnaA, and the 5' end of the dnaN gene, which codes for the beta subunit of DNA polymerase III. Further, we provide evidence that when cloned into pUC18, a plasmid that is nonreplicative in M. smegmatis, the DNA fragment containing the dnaA gene and its flanking regions rendered the former capable of autonomous replication in M. smegmatis. We suggest that the M. smegmatis chromosomal origin of replication is located within the 4-kb DNA fragment.     

Cloning and characterization of the alkA gene of Escherichia coli that encodes 3-methyladenine DNA glycosylase II

By in vitro recombination we have constructed hybrid plasmids which can suppress the increased methylmethane sulfonate sensitivity caused by the alkA1 mutation in Escherichia coli. Since the cloned DNA fragment was mapped at 44 to 45 min of the E. coli K12 genetic map, an area where the alkA gene is located, we conclude that the cloned DNA fragment contains the alkA gene itself but not other gene(s) that suppresses the alkA mutation. Specific labeling of plasmid-encoded proteins by the maxicell method revealed that the alkA codes for a polypeptide whose molecular weight is about 30,000. When cells harboring the alkA+ plasmids were grown in the presence of low doses of a simple alkylating agent (adapted condition), the activity of 3-methyladenine DNA glycosylase II was increased. The enzyme activity was copurified with the Mr 30,000 polypeptide. These results indicate that the alkA gene codes for 3-methyladenine DNA glycosylase II. Taking advantage of overproduction of the alkA protein in adapted cells that harbor multicopy plasmids carrying the alkA+ gene, 3-methyladenine DNA glycosylase II has been purified to apparent physical homogeneity.     

Physiological properties of cold-sensitive suppressor mutations of a temperature-sensitive dnaZ mutant of Escherichia coli

Suppressors of a temperature-sensitive dnaZ polymerization mutant of Escherichia coli have been identified by selecting temperature-insensitive revertants. Those suppressed strains which concomitantly became cold sensitive were chosen for further study. Intragenic suppressor mutations, which caused cold-sensitive defects in DNA polymerization, were located in dnaZ by transduction with lambda dnaZ+ phages. Extragenic suppressor mutations were mapped within the initiation gene dnaA. These suppressor-containing strains were defective in initiation at low temperature as determined by measurements of DNA synthesis in vivo and in toluene-treated cells. The occurrence of suppressor mutations of dnaZ(Ts) within the dnaA gene is considered evidence that the dnaA and dnaZ products interact in vivo. A second indication of a dnaA-dnaZ protein-protein interaction was provided by the observation that the introduction of additional copies of the dnaZ+ gene into a strain carrying the dnaA suppressor mutation was lethal [whether the strain was dnaZ+ or dnaZ(Ts)].     

Isolation and characterization of Escherichia coli dnaA amber mutants.

Specialized transducing phage lambda (formula, see text) dnaA-2 was mutagenized, and two derivatives designated lambda (formula) dnaA17(Am) and lambda (formula) dnaA452(Am) were obtained. They did not transduce such mutations as dnaA46, dnaA167, and dnaA5 when an amber suppressor was absent, but they did so in the presence of an amber suppressor. By contrast, they transduced the dna-806 and tna-2 mutations in the absence of an active amber suppressor. The dna-806 and tna-2 mutations are known to be located very close to the dnaA gene, but in separate cistrons. When ultraviolet light-irradiated uvrB cells were infected with the derivative phages and proteins specified by them were analyzed by gel electrophoresis, a 50,000-dalton protein was found to be specifically missing if an amber suppressor was absent. This protein was synthesized when an amber suppressor was present. The dnaA17(Am) mutation on the transducing phage genome was then transferred by genetic recombination onto the chromosome of an Escherichia coli strain carrying a temperature-sensitive amber suppressor supF6(Ts), yielding a strain which was temperature sensitive for growth and deoxyribonucleic acid replication. The temperature-sensitive trait was suppressed by supD, supE, or supF. We conclude that, most likely, the derivative phages acquired amber mutations in the dnaA gene whose product is a 50,000-dalton protein as identified by gel electrophoretic analysis.     

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.     

oriC region and replication termination site,dif, of the Xanthomonas campestris pv. campestris 17 chromosome

A 13-kb DNA fragment containing oriC and the flanking genes thdF, orf900, yidC, rnpA, rpmH, oriC, dnaA, dnaN, recF, and gyrB was cloned from the gram-negative plant pathogen Xanthomonas campestris pv. campestris 17. These genes are conserved in order with other eubacterial oriC genes and code for proteins that share high degrees of identity with their homologues, except for orf900, which has a homologue only in Xylella fastidiosa. The dnaA/dnaN intergenic region (273 bp) identified to be the minimal oriC region responsible for autonomous replication has 10 pure AT clusters of four to seven bases and only three consensus DnaA boxes. These findings are in disagreement with the notion that typical oriCs contain four or more DnaA boxes located upstream of the dnaA gene. The X. campestris pv. campestris 17 attB site required for site-specific integration of cloned fragments from filamentous phage phiLf replicative form DNA was identified to be a dif site on the basis of similarities in nucleotide sequence and function with the Escherichia coli dif site required for chromosome dimer resolution and whose deletion causes filamentation of the cells. The oriC and dif sites were located at 12:00 and 6:00, respectively, on the circular X. campestris pv. campestris 17 chromosome map, similar to the locations found for E. coli sites. Computer searches revealed the presence of both the dif site and XerC/XerD recombinase homologues in 16 of the 42 fully sequenced eubacterial genomes, but eight of the dif sites are located far away from the 6:00 point instead of being placed opposite the cognate oriC. The differences in the relative position suggest that mechanisms different from that of E. coli may participate in the control of chromosome replication.     

Cloning and identification of the Escherichia coli murB DNA sequence, which encodes UDP-N-acetylenolpyruvoylglucosamine reductase.

The murB gene, which complemented the UDP-N-acetylenolpyruvoylglucosamine reductase (EC 1.1.1.158) mutation in Escherichia coli ST5, was cloned from an E. coli chromosomal library. murB was subcloned on a 2.8-kb PvuII fragment into pUC19 and sequenced. A 1,029-bp open reading frame encoded a 342-amino-acid polypeptide of 37,859 Da. A DNA sequence homology search revealed that murB had almost 100% homology with a previously reported unidentified open reading frame, ORFII, at 89.9 min. Physical and genetic mapping results were consistent with this map position, and minicell analyses of murB subclones showed a plasmid-encoded protein of approximately 37,000 Da, which closely matched the calculated size of the murB protein.     

A Bacillus subtilis dnaG mutant harbours a mutation in a gene homologous to the dnaN gene of Escherichia coli

A dnaG mutation of Bacillus subtilis, dnaG5, was found to be linked closely to recF. We have reported previously that two putative dna genes, 'dnaA' and 'dnaN', highly homologous to Escherichia coli's dnaA and dnaN, respectively, were located adjacent to recF [Ogasawara et al., EMBO J., 4 (1985) 3345-3350]. Transformation by various fragments cloned from the 'dnaA'-recF region of the wild-type cell revealed that a 532-bp AluI fragment containing 5'-portion of the 'dnaN' gene could transform the dnaG5 mutation. The nucleotide (nt) sequence of the same fragment cloned from the mutant cell shows a single nt change in the ORF of 'dnaN' which in turn causes a single amino acid alteration from Gly to Arg. The 'dnaN' gene is now proven to be a dna gene, mutations in which result in instant arrest of chromosomal replication.     

Identification and characterization of the tktB gene encoding a second transketolase in Escherichia coli K-12.

We isolated a transposon Tn10 insertion mutant of Escherichia coli K-12 which could not grow on MacConkey plates containing D-ribose. Characterization of the mutant revealed that the level of the transketolase activity was reduced to one-third of that of the wild type. The mutation was mapped at 63.5 min on the E. coli genetic map, in which the transketolase gene (tkt) had been mapped. A multicopy suppressor gene which complemented the tkt mutation was cloned on a 7.8-kb PstI fragment. The cloned gene was located at 53 min on the chromosome. Subcloning and sequencing of a 2.7-kb fragment containing the suppressor gene identified an open reading frame encoding a polypeptide of 667 amino acids with a calculated molecular weight of 72,973. Overexpression of the protein and determination of its N-terminal amino acid sequence defined unambiguously the translational start site of the gene. The deduced amino acid sequence showed similarity to sequences of transketolases from Saccharomyces cerevisiae and Rhodobacter sphaeroides. In addition, the level of the transketolase activity increased in strains carrying the gene in multicopy. Therefore, the gene encoding this transketolase was designated tktB and the gene formerly called tkt was renamed tktA. Analysis of the phenotypes of the strains containing tktA, tktB, or tktA tktB mutations indicated that tktA and tktB were responsible for major and minor activities, respectively, of transketolase in E. coli.     

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.     

Isolation of recombinant plasmids and phage carrying the lexA gene of Escherichia coli K-12

The lexA gene of Escherichia coli K-12 was cloned from the plasmid pLC44-14 into pBR322. Plasmids carrying lexA+ were selected by their ability to complement a recessive tsl mutation, which is believed to be a mutation in lexA. The smallest lexA+ recombinant plasmid, pJL21, contained an EcoRI-PstI fragment 2.9 kilobases (kb) in length; two larger plasmids also contained this fragment, and genetic material to one or both sides of the EcoRI-PstI fragment. Plasmids homologous to pJL21, but carrying a dominant mutation, lexA3, or one of three recessive amber mutations in lexA, termed spr, were also isolated. To clone the EcoRI-PstI fragment onto a lambda vector, the PstI end was first converted to an EcoRI end by attachment of a 100-base pair PstI-EcoRI fragment isolated from the plasmid ColE1; the resultant EcoRI fragment was then cloned into the lambda vector lambda gt4. A restriction map of pLC44-14 was obtained for nine restriction enzymes. The orientation of this map was determined relative to the E. coli genetic map by complementation of the gene ubiA+ and by comparison with restriction enzyme digests of another plasmid, pLC11-9, which carries dnaB, a gene closely linked to lexA, but does not carry lexA.     

Escherichia coli K-12 mutants in which viability is dependent on recA function.

A gene required for growth and viability in recA mutants of Escherichia coli K-12 was identified. This gene, rdgB (for Rec-dependent growth), mapped near 64 min on the E. coli genetic map. In a strain carrying a temperature-sensitive recA allele, recA200, and an rdgB mutation, DNA synthesis but not protein synthesis ceased after 80 min of incubation at 42 degrees C, and there was extensive DNA degradation. The rdgB mutation alone had no apparent effect on DNA synthesis or growth; however, mutant strains did show enhanced intrachromosomal recombination and induction of the SOS regulon. The rdgB gene was cloned and its-gene product identified through the construction and analysis of deletion and insertion mutations of rdgB-containing plasmids. The ability of a plasmid to complement an rdgB recA mutant was correlated with its ability to produce a 25-kilodalton polypeptide as detected by the maxicell technique.