Conditional lethality of Escherichia coli strains carrying dnaE and dnaQ mutations

Borrelia burgdorferi ftsZ plays a role in cell division

ftsZ is essential for cell division in many microorganisms. In Escherichia coli and Bacillus subtilis, FtsZ plays a role in ring formation at the leading edge of the cell division septum. An ftsZ homologue is present in the Borrelia burgdorferi genome (ftsZ(Bbu)). Its gene product (FtsZ(Bbu)) is strongly homologous to other bacterial FtsZ proteins, but its function has not been established. Because loss-of-function mutants of ftsZ(Bbu) might be lethal, the tetR/tetO system was adapted for regulated control of this gene in B. burgdorferi. Sixty-two nucleotides of an ftsZ(Bbu) antisense DNA sequence under the control of a tetracycline-responsive modified hybrid borrelial promoter were cloned into pKFSS1. This construct was electroporated into a B. burgdorferi host strain carrying a chromosomally located tetR under the control of the B. burgdorferi flaB promoter. After induction by anhydrotetracycline, expression of antisense ftsZ RNA resulted in generation of filamentous B. burgdorferi that were unable to divide and grew more slowly than uninduced cells. To determine whether FtsZ(Bbu) could interfere with the function of E. coli FtsZ, ftsZ(Bbu) was amplified from chromosomal DNA and placed under the control of the tetracycline-regulated hybrid promoter. After introduction of the construct into E. coli and induction with anhydrotetracycline, overexpression of ftsZ(Bbu) generated a filamentous phenotype. This suggested interference of ftsZ(Bbu) with E. coli FtsZ function and confirmed the role of ftsZ(Bbu) in cell division. This is the first report of the generation of a B. burgdorferi conditional lethal mutant equivalent by tetracycline-controlled expression of antisense RNA.

Nucleotide sequences of dnaE, the gene for the polymerase subunit of DNA polymerase III in Salmonella typhimurium, and a variant that facilitates growth in the absence of another polymerase subunit

The dnaE gene of Salmonella typhimurium, like that of Escherichia coli, encodes the alpha subunit containing the polymerase activity of the principal replicative enzyme, DNA polymerase III. This gene, or one nearby, has been identified as the locus of suppressor mutations that promote growth by cells deleted for dnaQ, the gene for the editing subunit of this enzyme complex. Using a combination of nucleotide sequencing and marker rescue experiments, the alteration in one such suppressor was identified as a valine-to-glycine substitution at amino acid 832 of the 1,160-amino-acid alpha polypeptide. The alpha polypeptides of E. coli and S. typhimurium are identical in size and in 97% of their amino acid residues. Their identity includes the valine residue that was changed in the suppressor allele of S. typhimurium. We also localized a temperature-sensitive dnaE mutation to the 3' half of dnaE.

Isolation and characterization of mutants with deletions in dnaQ, the gene for the editing subunit of DNA polymerase III in Salmonella typhimurium

dnaQ (mutD) encodes the editing exonuclease subunit (epsilon) of DNA polymerase III. Previously described mutations in dnaQ include dominant and recessive mutator alleles as well as leaky temperature-sensitive alleles. We describe the properties of strains bearing null mutations (deletion-substitution alleles) of this gene. Null mutants exhibited a growth defect as well as elevated spontaneous mutation. As a consequence of the poor growth of dnaQ mutants and their high mutation rate, these strains were replaced within single colonies by derivatives carrying an extragenic suppressor mutation that compensated the growth defect but apparently not the mutator effect. Sixteen independently derived suppressors mapped in the vicinity of dnaE, the gene for the polymerization subunit (alpha) of DNA polymerase III, and one suppressor that was sequenced encoded an altered alpha polypeptide. Partially purified DNA polymerase III containing this altered alpha subunit was active in polymerization assays. In addition to their dependence on a suppressor mutation affecting alpha, dnaQ mutants strictly required DNA polymerase I for viability. We argue from these data that in the absence of epsilon, DNA replication falters unless secondary mechanisms, including genetically coded alteration in the intrinsic replication capacity of alpha and increased use of DNA polymerase I, come into play. Thus, epsilon plays a role in DNA replication distinct from its known role in controlling spontaneous mutation frequency.

Mechanisms of mutagenesis in the Escherichia coli mutator mutD5: role of DNA mismatch repair

To investigate the mechanisms of spontaneous mutation in the Escherichia coli mutD5 mutator strain, 502 mutations generated in this strain in the N-terminal part of the lacI gene were sequenced (i-d mutations). Since the mutator strength of this strain depends on the medium in which it grows, mutations were analyzed in both minimal medium (moderate mutator activity) and rich medium (high mutator activity). In either case, 95% of all mutations were base substitutions and 5% were single-base deletions. However, the nature and site distribution of the base substitutions differed dramatically for the two conditions. In minimal medium (mutation frequency, 480-fold above background), a majority (62%) were transversions, notably A.T----T.A at three 5'-GTGG-3' sequences. Most (64%) of the transitions under this condition occurred at specific sequences that are suggestive of a "dislocation" type of mutagenesis. In rich medium (mutation frequency, 37,000-fold above background), 90% of the base substitutions were transitions. These observations suggest that different modes of mutagenesis operate under the two conditions. mutD5 cells have been reported to be defective in exonucleolytic proofreading during DNA replication. The present data suggest that mutD cells in rich medium also suffer a defect in mutHLS-encoded mismatch correction. This hypothesis was confirmed by the direct measurement of mismatch repair in mutD5 cells by transfection of M13mp2 heteroduplex DNA.

Interactions between epsilon, the proofreading subunit of DNA polymerase III, and proteins involved in the SOS response of Escherichia coli

Epsilon, a fidelity subunit of Escherichia coli DNA Polymerase III, is encoded by dnaQ+. dnaQ49 is a recessive allele that confers temperature-sensitive and salt-suppressible phenotypes for both replication fidelity and viability. SOS mutagenesis in E. coli is regulated by LexA and requires activated RecA (RecA*) and the products of the umuDC operon. dnaQ49 strains with various recA, lexA and umuDC alleles were constructed to determine if activities induced as part of the SOS response influence epsilon activity. We found: (1) both UmuDC and RecA* independently enhance the dnaQ49 mutator phenotype, and (2) expression of RecA* activity in the absence of UmuDC function increases the temperature sensitivity for viability of dnaQ49. These results support the hypothesis that RecA and one or both of the UmuDC proteins interact with the replication complex during SOS mutagenesis.

Cloning and characterization of an albicidin resistance gene from Klebsiella oxytoca

A DNA fragment containing a gene for resistance to the antibiotic albicidin was isolated from Klebsiella oxytoca and shown to be expressed in Escherichia coli, where it also protected bacteriophage T7 replication from inhibition by albicidin. In vivo translation analysis demonstrated that the cloned 2.2kb DNA fragment coded for a 36 kiloDalton (kD) protein and a 25kD protein. The DNA sequence was determined for a 654-base-pair open reading frame contained within a 1.2kb subcloned DNA fragment encoding albicidin resistance. The predicted molecular weight of the polypeptide translated from the open reading frame was 25.8kD. A putative Shine-Dalgarno sequence precedes the open reading frame but a potential promoter sequence was not detected. A possible rho-independent transcription termination signal was found directly following the stop codon. The functional protein for albicidin resistance was isolated and purified. Both the molecular weight and NH2-terminal amino acid sequence of this protein correspond with that predicted from the DNA sequence of the open reading frame. The cloned albicidin resistance gene had no effect on the tsx (nupA) nucleoside uptake gene associated with spontaneous albicidin resistance in E. coli; also, it did not complement any of a range of E. coli DNAts mutants at restrictive temperatures. The cloned resistance gene product remained intracellular in exponential cultures of K. oxytoca and E. coli. Cell-free extracts from E. coli containing the resistance gene protected a sensitive strain of E. coli from inhibition by albicidin, as did the purified albicidin resistance protein. The mechanism of this albicidin resistance protein involved binding to albicidin to form a complex without antibiotic activity, but without catalysing further chemical modification of the antibiotic.

RNase H and replication of ColE1 DNA in Escherichia coli

Amber mutations within the rnh (RNase H) gene of Escherichia coli K-12 were isolated by selecting for bacteria capable of replicating in a sup+ background replication-defective cer-6 mutant of the ColE1 replicon. The cer-6 mutation is an alteration of one base pair located 160 nucleotides upstream of the unique replication origin of this plasmid. Subsequently, we determined the DNA alterations present within these mutants. ColE1 DNA replicated in rnh(Am) recA cells, indicating that (i) RNase H, which has been shown to be absolutely required for in vitro initiation of ColE1 DNA replication, is dispensable in vivo, and (ii) ColE1 replication in the absence of RNase H is not dependent on "stable DNA replication," which has been reported to be an alternative mode of chromosomal DNA replication. Another class of bacterial mutations was also isolated. These mutations, named herB, suppressed cer-6 replication in rnh+ bacteria. herB mutations mapped close to the polA gene on the E. coli chromosome and increased the activity of DNA polymerase I. These findings suggest that when the DNA polymerase I has an opportunity to initiate DNA synthesis before RNase H acts, the replication-defective cer-6 mutant or the wild-type ColE1 replicates in E. coli.

Mutational specificity of a proof-reading defective Escherichia coli dnaQ49 mutator

The dnaQ (mutD) gene product which encodes the epsilon-subunit of the DNA polymerase III holoenzyme has a central role in controlling the fidelity of DNA replication because both mutD5 and dnaQ49 mutations severely decrease the 3'-5' exonucleolytic editing capacity. It is shown in this paper that more than 95% of all dnaQ49-induced base pair substitutions are transversions of the types G:C-T:A and A:T-T:A. Not only is this unusual mutational specificity precisely that observed recently for a number of potent carcinogens such as benzo(a) pyrene diolepoxide (BPDE) and aflatoxin B1 (AFB1), which are dependent on the SOS system to mutagenize bacteria, but it is also seen for the constitutively expressed SOS mutator activity in E. coli tif-1 strains as well as for the SOS mutator activity mediated gap filling of apurinic sites. Because the G:C-T:A and A:T-T:A transversions can either result from the insertion of an adenine across from apurinic sites or arise due to the incorporation of syn-adenine opposite a purine base, we postulate that the DNA polymerase III holoenzyme also has a reduced discrimination ability in a dnaQ49 background. The introduction of a lexA (Ind-) allele, which prevents the expression of SOS functions, led to a significant reduction in the dnaQ49-caused mutator effect. Both, the mutational specificity observed and the partial lexA+ dependence of the mutator effect provoke a reanalysis of the hypothesis that the DNA polymerase III holoenzyme can be converted into the postulated but until now unidentified SOS polymerase.

Structure and expression of the dnaQ mutator and the RNase H genes of Escherichia coli: overlap of the promoter regions

A 1.6-kilobase-pair DNA fragment derived from the Escherichia coli chromosome was analyzed by Tn3 transposon insertion and deletion mapping to locate a mutator gene, dnaQ (mutD), and the rnh gene that codes for RNase H. When a strong promoter, PL of lambda phage, was placed at the right- and left-side of the cloned DNA fragment, the dnaQ protein and RNase H, respectively were overproduced. These results suggested that the two genes are transcribed in opposite directions and that their promoters are located in a narrow region between the genes. Nucleotide sequence analysis confirmed this and further revealed that transcriptional and translational initiation signals for the two genes overlap. From the sequence data it was deduced that the dnaQ protein and RNase H consist of 243 and 155 triplets and have molecular weights of 27,500 and 17,500, respectively. dnaQ81 amber mutant showed two codon alterations, CAG(glutamine-195) leads to TAG(amber) and ACA(threonine-193) leads to ATA(isoleucine). The dnaQ-lacZ and the rnh-lacZ fused genes were constructed and hybrid proteins with beta-galactosidase activity were produced. From beta-galactosidase levels it was estimated that the promoter for dnaQ is 5 times more active than that for rnh.

A dominant (mutD5) and a recessive (dnaQ49) mutator of Escherichia coli

The two known strong mutators of Escherichia coli K12, mutD5 (Degnen & Cox, 1974) and dnaQ49 (Horiuchi et al., 1978), are located at almost the same position, at five minutes on the linkage map. To clarify the genetical and functional relationships between these two mutators, we have constructed hybrid plasmids and phages carrying dnaQ+ or mutD5 by using in vivo and in vitro recombination techniques and examined their effect on the phenotype of wild-type or mutant bacteria. The results indicated that the mutD5 mutator is dominant over the wild-type allele whereas dnaQ49 is recessive. Thus, mutD5 plasmid or mutD5 transducing lambda phage can be used to convert a wild-type strain to a highly mutable strain. Both dnaQ+ and mutD5 plasmids carried a 1.5 X 10(3) base DNA fragment derived from the E. coli chromosome and they were indistinguishable from each other by restriction enzyme analysis. Moreover, specific labeling of the plasmid-encoded proteins by the maxicell method revealed that the mutD5 plasmid codes for two proteins, one whose molecular weight is 25,000 and the other whose molecular weight is 21,000, which correspond to the dnaQ protein and RNase H, respectively. Insertion of the gamma delta sequence into the mutD gene of the plasmid resulted in disappearance of the 25,000 Mr protein. These results suggested that the dnaQ49 and mutD5 mutator are mutations that have arisen in a single gene, though they differ in many respects.

Mutator strains of Escherichia coli, mutD and dnaQ, with defective exonucleolytic editing by DNA polymerase III holoenzyme

The closely linked mutD and dnaQ mutations confer a vastly increased mutation rate on Escherichia coli and thus might define a gene with a central role in the fidelity of DNA replication. To look for the biochemical function of the mutD gene product, we have measured the 3' leads to 5' exonucleolytic editing activity of polymerase III holoenzyme from mutD5 and dnaQ49 mutants. The editing activities of the mutant enzymes are defective compared to wild type, as judged by two assays: (i) decreased excision of a terminal mispaired base from a copolymer substrate and (ii) turnover of dTTP to dTMP during replication with a phage G4 DNA template. Thus, the mutD (dnaQ) gene product is likely to control the editing (proofreading) capacity of polymerase III holoenzyme.

Structure and coding properties of a dominant Escherichia coli mutator gene, mutD

The region of the Escherichia coli chromosome coding for the mutD gene was cloned, mutD5 function resides on a 1.2-kilobase fragment coding for a 28-kilodalton (kDa) protein. A deletion end-point analysis shows that the presence of the 28-kDa protein is required for mutD5 function and suggests that the mutD functional region has sufficient capacity to code for a second polypeptide of approximately 20 kDa. Plasmids carrying the mutD5 and mut+ alleles both produce the 28-kDa species. The product of mutD5 is dominant when carried by single and multicopy plasmids. The product of mut+ is dominant only on multicopy plasmids. Thus, mutD5 exhibits negative complementation. We suggest that the 28-kDa protein participates in a multimeric structure, perhaps at the replication fork.

Isolation of conditional lethal mutator mutants of Escherichia coli by localized mutagenesis

By using localized mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine, we isolated 39 temperature-sensitive growth mutants that exhibited high mutability when the bacteria were grown at the permissive temperature. Two of the mutations, dnaQ186 and dnaQ231, were shown to be new alleles of the dnaQ gene by genetic mapping and complementation tests with the dnaQ49 mutation previously isolated. They shared common properties with the dnaQ49 strain, but their mutator activity was not temperature dependent. The dnaQ mutants exhibited increased sensitivity to inhibitors of DNA gyrase and to DNA intercalating and alkylating agents.

Identification of the dnaQ gene product and location of the structural gene for RNase H of Escherichia coli by cloning of the genes

By in vitro recombination we have constructed hybrid plasmids capable of complementing a conditional lethal mutator mutation, dnaQ49, in Escherichia coli K12. The dnaQ+ plasmids consist of a full-length pBR322 DNA and a 1.5-kilobase DNA fragment derived from the E. coli chromosome. Specific labeling of plasmid-encoded proteins by the maxicell method revealed that the 1.5-kilobase insert codes for two proteins, one whose molecular weight is 25,000 [the 25-kilodalton (kDal) protein] and the other whose molecular weight is 21,000 (the 21-kDal protein). Because insertion of gamma delta sequence into the dnaQ gene of the plasmid resulted in disappearance of the 25-kDal protein, it was concluded that the 25-kDal protein is the dnaQ gene product. The 21-kDal protein was identified as RNase H on the basis of the following evidence. (i) Cells harboring the dnaQ+ plasmids, with or without the gamma delta insertion in the dnaQ gene, had a 5- to 7-fold higher level of RNase H activity than cells harboring pBR322. (ii) After induction of cells that are lysogenized with dnaQ+-transducing lambda phages, RNase H activity increased considerably. A similar high level of RNase H activity was observed with transducing phages whose dnaQ function was inactivated by insertion of a transposon, Tn3, into the gene, (iii) The plasmid-encoded RNase H, labeled with [35S]methionine, was purified in a manner essentially similar to that of the chromosome-encoded enzyme. These results suggest that the dnaQ gene and the structural gene for RNase H, termed gene rnh, are closely linked and located at 5 min on the linkage map.