Effects of rifampicin resistant rpoB mutations on antitermination and interaction with nusA in Escherichia coli

Rifampicin resistant (Rifr mutations map in the rpoB gene encoding the beta subunit of Escherichia coli RNA polymerase. We have used our collection of 17 sequenced Rifr mutations to investigate the involvement of E. coli RNA polymerase in the antitermination systems enhancing expression of delayed early lambda genes or stable RNA. We have found that Rifr mutations affect both lambda N-mediated antitermination and the cellular antitermination system involved in synthesis of stable RNA. Because NusA is involved in antitermination and termination, we also investigated the interaction of NusA and RNA polymerase by determining whether Rifr mutations alter NusA-dependent termination or antitermination in cells with defective nusA alleles. We have shown that Rifr mutations can either enhance or suppress the phenotypes of defective nusA alleles. Most Rifr mutations alter the temperature range over which the nusA1 allele supports lambda N-mediated antitermination. In addition, a number of Rifr alleles restore termination to the nusA10(Cs) and the nusA11(Ts) mutants defective in this process. Our results indicate that the region of the rpoB gene defined by the Rifr mutations is involved in the antitermination process and affects the activity of the NusA protein directly or indirectly.     

RNA polymerase-rifamycin. A molecular model of inhibition

By fluorimetric titration of Rifs (E. coli B) and Rifr (E. coli rpoB255) RNA polymerases with rifamycin, the mutant polymerase was demonstrated to bind rifamycin. A comparison of spatial structures of rifamycin and dinucleotide fragment of RNA in the hybrid with DNA revealed their similarity. Taking into account this structural similarity and also the fact that two phosphodiester bonds can be formed by RNA polymerase in the presence of rifamycin, a model for the inhibition mode was proposed. According to this model, rifamycin occupies the place of two terminal nucleotides of synthesized, but not translocated pentanucleotide in the transcribing complex. Asp-516 of the wild type beta-subunit was assumed to form a hydrogen bond with the rifamycin C(23) hydroxyl group. On the base of this model, reduced "cycling" synthesis of tetra-, penta-... up to decanucleotides by the Rifr RNA polymerase, in comparison with Rifs, was predicted.     

Mapping and sequencing of mutations in the Escherichia coli rpoB gene that lead to rifampicin resistance

Rifampicin is an antibiotic that inhibits the function of RNA polymerase in eubacteria. Mutations affecting the beta subunit of RNA polymerase can confer resistance to rifampicin. A large number of rifampicin-resistant (hereafter called Rifr) mutants have been isolated in Escherichia coli to probe the involvement of RNA polymerase in a variety of physiological processes. We have undertaken a comprehensive analysis of Rifr mutations to identify their structural and functional effects on RNA polymerase. Forty-two Rifr isolates with a variety of phenotypes were mapped to defined intervals within the rpoB gene using a set of deletions of the rpoB gene. The mutations were sequenced. Seventeen mutational alterations affecting 14 amino acid residues were identified. These alleles are located in three distinct clusters in the center of the rpoB gene. We discuss the implications of our results with regards to the structure of the rifampicin binding site.     

Escherichia coli RNA polymerase mutants that enhance or diminish the SOS response constitutively expressed in the absence of RNase HI activity.

Escherichia coli rnhA mutants lacking RNase HI chronically express the SOS response (T. Kogoma, X. Hong, G. W. Cadwell, K. G. Barnard, and T. Asai, Biochimie 75:89-99, 1993). Seventeen rpoB (Rifr) mutant alleles, which encode altered beta subunits of RNA polymerase, giving rise to resistance to rifampin, were screened for the ability to enhance or diminish constitutive expression of the SOS response in rnhA mutants. Two mutations, rpoB3595 and rpoB2, were found to enhance the SOS response 5- and 2.5-fold, respectively, only when RNase HI is absent. These mutations rendered rnhA mutant cells very sensitive to broth; i.e., the plating efficiency of the double mutants was drastically reduced when tested on broth plates. Two mutations, rpoB8 and rpoB3406, were found to diminish constitutive SOS expression in rnhA mutants by 43 and 30%, respectively. It was suggested that RNA polymerase may have a property that influences the size of DNA-RNA hybrids, the frequency of their formation, or both and that the property resides at least in part in the beta subunit of the polymerase.     

Dominant lethal mutations in the dnaB helicase gene of Salmonella typhimurium

A class of dominant lethal mutations in the dnaB (replicative helicase) gene of Salmonella typhimurium is described. The mutated genes, when present on multicopy plasmids, interfered with colony formation by Escherichia coli host strains with a functional chromosomal dnaB gene. The lethal phenotype was expressed specifically in supE (glutamine-inserting) host strains and not in Sup+ strains, because the mutant genes, by design, also possessed an amber mutation derived from a glutamine codon. Mutations located at 11 sites by deletion mapping and DNA sequence analysis varied in the temperature dependence and severity of their lethal effects. None of the mutations complemented a dnaB(Ts) host strain at high temperature (42 degrees C). Therefore, these nonfunctional DnaB proteins must engage some component(s) of the DNA replication machinery and inhibit replication. These mutations are predicted to confer limited, specific defects in either the catalytic activity of DnaB or the ability of DnaB to interact with one of its ligands such as DNA, nucleotide, or another replication protein. The variety of mutant sites and detailed phenotypes represented in this group of mutations may indicate the operation of more than one specific mechanism of lethality.     

Genes that protect against the host-killing activity of the E3 protein of Bacillus subtilis bacteriophage SPO1.

A cloned rpoB gene, specifying an apparently mutant RNA polymerase beta subunit, protected Escherichia coli against the cytocidal effects of the E3 protein of bacteriophage SPO1, suggesting that RNA polymerase is the primary cellular target of the E3 protein. Two segments of the wild-type E. coli genome, one of which specifies a suppressor of dnaK mutations, and thus, possibly, a molecular chaperone, also provided protection when overexpressed, but wild-type rpoB did not.     

F'-plasmid transfer from Escherichia coli to Pseudomonas fluorescens.

Various F' plasmids of Escherichia coli K-12 could be transferred into mutants of the soil strain 6.2, classified herein as a Pseudomonas fluorescens biotype IV. This strain was previously found to receive Flac plasmid (N. Datta and R.W. Hedges, J. Gen Microbiol. 70:453-460, 1972). ilv, leu, met, arg, and his auxotrophs were complemented by plasmids carrying isofunctional genes; trp mutants were not complemented or were very poorly complemented. The frequency of transfer was 10(-5). Subsequent transfer into other P. fluorescens recipients was of the same order of magnitude. Some transconjugants were unable to act as donors, and these did not lose the received information if subcultured on nonselective media. Use of F' plasmids helped to discriminate metabolic blocks in P. fluorescens. In particular, metA, metB, and argH mutants were so distinguished. In addition, F131 plasmid carrying the his operon and a supD mutation could partially relieve the auxotrophy of thr, ilv, and metA13 mutants, suggesting functional expression of E. coli tRNA in P. fluorescens. In P. fluorescens metA Rifr mutants carrying the F110 plasmid, which carried the E. coli metA gene and the E. coli rifs allele, sensitivity to rifampin was found to be dominant at least temporarily over resistance. This suggests interaction of E. coli and P. fluorescens subunits of RNA polymerase. his mutations were also complemented by composite P plasmids containing the his-nif region of Klebsiella pneumoniae (plasmids FN68 and RP41). nif expression could be detected by acetylene reduction in some his+ transconjugants. The frequency of transfer of these P plasmids was 5 X 10(-4).     

Mutations in the Escherichia coli RNA-polymerase beta-subunit gene cloned in a multicopy plasmid

A multicopy plasmid pLMN1 expressing a wild type rpoB gene encoding Escherichia coli RNA polymerase beta subunit gene was constructed. Introduction of this plasmid into rifampicin-resistant RpoB mutants makes them rifampicin-sensitive. Rifampicin-resistant clones appear in such strains with frequencies up to 10(-3), due to recombinational (recA-dependent) transfer of rif-r mutations from chromosome to pLMN1. This provides a simple selection procedure for transfer of any rpoB mutation, together with a rif-r mutation from a chromosome to pLMN1. In this way, we transferred rpoB22 amber mutation to pLMN1 for localization of the mutant codon by DNA sequencing.     

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.     

Overexpression and purification of a biologically active rifampicin-resistant beta subunit of Escherichia coli RNA polymerase

The gene rpoB (rifD 18), which encodes rifampicin-resistant beta subunit of Escherichia coli RNA polymerase, has been placed on an overexpression plasmid under the control of bacteriophage T7 promoter. Induction of the T7 RNA polymerase gene in the host cells resulted in extensive overproduction of the beta polypeptide. Most of the overproduced material was recovered from cell lysates in insoluble form and was solubilized by extraction with 6 M urea. Purified overproduced beta subunit was added, in molar excess, to urea-denatured rifampicin-sensitive RNA polymerase. Upon removal of urea by dialysis, the reconstituted enzyme became rifampicin-resistant, indicating that overproduced beta subunit can be efficiently assembled into functional holoenzyme.     

Mutation slowing down the degradation of the beta beta'-subunits of Escherichia coli RNA-polymerase

The rpoC1 ts mutation affecting the RNA polymerase beta' subunit accelerates synthesis of RNA polymerase beta beta' subunits at 42 degrees C, while the surplus amount of subunits degrades in an hour's time. In a Ts strain with two RNA polymerase mutations, rpoC1 and rpoB251, we obtained a ts+ reversion designated opr24 which slows down degradation of surplus beta beta' subunits. The slowing down of degradation and the resulting accumulation of beta beta' subunits does not affect the kinetics of beta beta' subunit synthesis after the transfer to 42 degrees C. The effects of the opr24 are allele non-specific. The mutation also slows down degradation of beta' subunit and the amber fragment of beta subunit in the strain with subunit amber mutation rpoB22. Besides, the opr24 mutation reduces proteolysis of anomalous proteins containing canavanine. The opr24 mutation has been mapped between 17 and 21 minutes on the Escherichia coli map.     

Homology modeling of wild-type, D516V, and H526L Mycobacterium tuberculosis RNA polymerase and their molecular docking study with inhibitors

Rifamicyns (Rifs) are antibiotic widely used for the treatment of tuberculosis (TB); nevertheless, their efficacy has been limited by a high percentage of mutations, principally in the rpoB gene. In this work, the first three-dimensional molecular model of the hypothetical structures for the wild-type and D516V and H526L mutants of Mycobacterium tuberculosis (mtRNAP) were elucidated by a homology modeling method. In addition, the orientations and binding affinities of some Rifs with those new structures were investigated. Our findings could be helpful for the design of new more potent rifamycin analogs.     

Mutagenicity of the cytidine analog zebularine in Escherichia coli

We have examined the mutagenic properties of zebularine, a cytidine analog lacking the amino group at C-4 that has potential use in chemotherapy. Because the hydrate is a strong inhibitor of cytidine deaminase, its use can enhance the potency of other cytosine based compounds such as 5-azacytidine (5AzaC) and cytosine arabinoside (ara-C) that are inactivated by cytidine deaminase. Using the newly developed rpoB/Rifr system in Escherichia coli, we examined base substitution mutations caused by zebularine in the chromosomal rpoB gene. Zebularine is a potent mutagen that causes mainly G : C --> A : T transitions and favors certain hotspots. Mutations are not specific to the rpoB gene, since there is also a strong induction of mutations in the thyA gene. In the absence of mismatch repair, zebularine induces both base substitutions and frame shifts at rates well above those seen in wild-type strains treated with zebularine or in mismatch repair deficient strains without treatment. The nature of these induced mutations indicates that zebularine is stimulating the induction of increased replication errors, in addition to the targeted G : C --> A : T mutations, and that these errors are normally repaired by the mismatch repair system.     

Synergistic effect of himA and gyrB mutations: evidence that him functions control expression of ilv and xyl genes.

We have constructed Escherichia coli strains containing mutations at two different loci, both originally selected for failure to support lambda site-specific recombination: himA and gyrB-him(Ts). Although the gyrB-him(Ts) mutations by themselves reduce supercoiling at high temperature, the double mutants show a far greater effect on supercoiling. Our studies show that growth of phage lambda is severely inhibited and that maintenance of plasmid pBR322 is extremely unstable in the double mutants. Physiological studies also reveal that the double mutants are isoleucine auxotrophs at 42 degrees C. The fact that himA mutants are isoleucine auxotrophs at 42 degrees C in the presence of leucine suggests that a significant component of the isoleucine auxotrophy of the double mutants is a result of the himA mutation. The himA gene encodes the alpha subunit of a protein called the integration host factor. Since mutations in the hip or himD gene encoding beta, the other subunit of the integration host factor, also result in isoleucine auxotrophy in the presence of leucine, we suggest that the integration host factor regulates the synthesis of at least one of the enzymes in the ilv pathway, acetohydroxyacid synthase I, which is encoded by the ilvB gene. Studies of the utilization of various sugars as the sole carbon source suggest that the integration host factor controls expression of some gene(s) involved in the utilization of xylose.     

A targeted gene knockout method using a newly constructed temperature-sensitive plasmid mediated homologous recombination in Bifidobacterium longum

Bifidobacteria are the main component of the human microflora. We constructed a temperature-sensitive (Ts) plasmid by random mutagenesis of the Bifidobacterium-Escherichia coli shuttle vector pKKT427 using error-prone PCR. Mutant plasmids were introduced into Bifidobacterium longum 105-A and, after screening approximately 3,000 colonies, candidate clones that grew at 30?°C but not at 42?°C were selected. According to DNA sequence analysis of the Ts plasmid, five silent and one missense mutations were found in the repB region. The site-directed mutagenesis showed only the missense mutation to be relevant to the Ts phenotype. We designated this plasmid pKO403. The Ts phenotype was also observed in B. longum NCC2705 and Bifidobacterium adolescentis ATCC15703. Single-crossover homologous-recombination experiments were carried out to determine the relationship between the length of homologous sequences encoded on the plasmid and recombination frequency: fragments greater than 1?kb gave an efficiency of more than 10(3) integrations per cell. We performed gene knockout experiments using this Ts plasmid. We obtained gene knockout mutants of the pyrE region of B. longum 105-A, and determined that double-crossover homologous recombination occurred at an efficiency of 1.8?%. This knockout method also worked for the BL0033 gene in B. longum NCC2705.     

Requirement of the Escherichia coli dnaA gene product for plasmid F maintenance.

There are DnaA protein-binding sites in at least one F origin of replication, and only potentially leaky dnaA(Ts) mutations had ever been used in previous studies indicating that F replication was independent of the dnaA gene product. Here we show that an Escherichia coli dnaA::Tn10 host which does not make a dnaA gene product cannot sustain autonomous or integrated F plasmid maintenance.     

Suppression of a thermosensitive dnaA mutation of Escherichia coli by bacteriophage P1 and P7.

Like other plasmids, the P1 and P7 prophages suppress E. coli dnaA(Ts) mutations by integrating into the host chromosome. This conclusion is supported by three lines of evidence: (1) Alkaline sucrose gradients reveal the absence of plasmid DNA in suppressed lysogens; (2) the prophage is linked to host chromosomal markers in conjugation; and (3) auxotrophs whose defect is linked to the prophage are found among suppressed colonies. No phage or bacterial mutation is required for suppression. Integrative suppression by P1 and P7, unlike suppression by F, does not require the host recA⁺ function. Among suppressed P7 lysogens are some that do not produce phage; these contain defective prophages. The genetic extent of the deletions contained by these defective prophages delineates the prophage regions which are not necessary for suppression of dnaA(Ts). The possible mechanisms of integration and deletion formation are discussed.     

The mutation that makes Escherichia coli resistant to lambda P gene-mediated host lethality is located within the DNA initiator Gene dnaA of the bacterium

Earlier, we reported that the bacteriophage lambda P gene product is lethal to Escherichia coli, and the E. coli rpl mutants are resistant to this lambda P gene-mediated lethality. In this paper, we show that under the lambda P gene-mediated lethal condition, the host DNA synthesis is inhibited at the initiation step. The rpl8 mutation maps around the 83 min position in the E. coli chromosome and is 94 % linked with the dnaA gene. The rpl8 mutant gene has been cloned in a plasmid. This plasmid clone can protect the wild-type E. coli from lambda P gene-mediated killing and complements E. coli dnaAts46 at 42 degrees C. Also, starting with the wild-type dnaA gene in a plasmid, the rpl-like mutations have been isolated by in vitro mutagenesis. DNA sequencing data show that each of the rpl8, rpl12 and rpl14 mutations has changed a single base in the dnaA gene, which translates into the amino acid changes N313T, Y200N, and S246T respectively within the DnaA protein. These results have led us to conclude that the rpl mutations, which make E. coli resistant to lambda P gene-mediated host lethality, are located within the DNA initiator gene dnaA of the host.